The present invention relates to internal combustion engines. More specifically, the present invention relates cylinders for internal combustion engines.
Increasingly stringent regulations for two-stroke engines necessitate a reduction in emissions. Emissions reduction techniques have so far included engine calibration strategies using injection timing to minimize lost fuel at the expense of mixture preparation and power. Traditional calibration strategies for reducing emissions focus on timing the Start of Injection (SOI) to minimize the amount of lost fuel. Since injection occurs during cylinder scavenging, the path the fuel cloud takes is strongly influenced by the scavenging pattern produced by the transfer ports. The flow pattern which provides good power performance in carbureted engines also convects fuel spray toward the exhaust port in the direct injection engine. These fuel losses can be minimized by allowing less time for the scavenging flows to convect fuel to the exhaust port. However, this strategy also reduces the amount of time for the fuel spray to mix with the air delivered during scavenging resulting in a reduced power output.
It would be desirable to further reduce these fuel losses out of the exhaust port without excessively degrading mixture preparation and trapped oxygen. It is therefore desirable to optimize the scavenging pattern to maximize fuel trapping without sacrificing mixture preparation.
It would be desirable to have a two-stroke, direct injection, internal combustion engine with reduced emissions, increased power output and improved fuel economy. It would also be desirable to achieve these results without increasing the size of the bore, bore spacing or stroke of the engine compared to that of current generation engines in order to remain within the current constraints of cost, weight, commonality, and engine envelope targets.
It is an object of the present invention to ameliorate at least some of the inconveniences present in the prior art.
In one aspect, a cylinder for an internal combustion engine is provided. The cylinder comprises a cylinder axis, a cylindrical wall, and an exhaust port defined in the wall. At least one central transfer port is defined in the wall. Each of the at least one central transfer port has a transfer channel extending therefrom. For each of the at least one central transfer port, an angle about the cylinder axis between a center of the central transfer port and a center of the exhaust port is greater than 135° and less than or equal to 180°. At least two side transfer ports are defined in the wall. Each of the at least two side transfer ports has a transfer channel extending therefrom. For each of the at least two side transfer ports, an angle about the cylinder axis between a center of the side transfer port and the center of the exhaust port is less than or equal to 135°.
In another aspect, for each of the at least two side transfer ports, the corresponding transfer channel has at least one wall adapted to guide air flow into the cylinder towards the at least one central transfer port.
In another aspect, for each of the at least one central transfer port, the corresponding transfer channel has at least one wall adapted to direct air flow into the cylinder toward the exhaust port.
In an additional aspect, each transfer channel is defined by an outer surface of the cylinder adjacent to the corresponding one of the at least one central transfer port and at least two side transfer ports, two side walls extending from a periphery of the corresponding one of the at least one central transfer port and at least two side transfer ports, a rear wall extending between the two side walls and spaced from the outer surface, and an upper wall extending from the periphery of the corresponding one of the at least one central transfer port and at least two side transfer ports between the two side walls and the rear wall.
In a further aspect, for each transfer channel: the rear wall and the two side walls extend generally parallel to the cylinder axis.
In another aspect, for each transfer channel corresponding to the at least two side transfer ports, a first portion of one of the two side walls extends parallel to a plane defined by the cylinder axis and the center of the exhaust port.
In yet another aspect, for each transfer channel corresponding to the at least two side transfer ports, the one of the two side walls has a second portion extending between the first portion and the corresponding side transfer port. A chord is defined by the periphery of the corresponding side transfer port in a plane normal to the cylinder axis and containing the center of the corresponding side transfer port. An angle between the second portion and the chord is less than or equal to 90°.
In a further aspect, for each transfer channel corresponding to the at least two side transfer ports, the two side walls converge towards one another as they extend toward the rear wall.
In a further aspect, for each transfer channel corresponding to the at least two side transfer ports, at least a portion of the other of the two side walls extends parallel to the one of the two side walls. In another aspect, the rear wall is perpendicular to the two side walls.
In a further aspect, for each transfer channel corresponding to the at least two side transfer ports, an angle between the upper wall and the rear wall is greater than 90°.
In a further aspect, the at least one central transfer port includes a left central transfer port and a right central transfer port disposed circumferentially symmetrically with respect to the exhaust port.
In a further aspect, the angle about the cylinder axis between the centers of the left central transfer port and the right central transfer port is less than 90°.
In an additional aspect, the at least two side transfer ports include a left side transfer port and a right side transfer port disposed circumferentially symmetrically with respect to the exhaust port. For each of the left side transfer port and the right side transfer port, the angle about the cylinder axis between the centers of the exhaust port and the side transfer port is less than 90°.
In an additional aspect, the surface area of each of the at least two side transfer ports is larger than the surface area of each of the at least one central transfer port.
In yet another aspect, the at least one central transfer port is one central transfer port, and the angle about the cylinder axis between the center of the exhaust port and the center of the central transfer port is 180°.
In a further aspect, the at least two side transfer ports includes a first left side transfer port, a first right side transfer port, a second left side transfer port, and a second right side transfer port. The first left side transfer port and the first right side transfer port are disposed circumferentially symmetrically with respect to the exhaust port. The second left side transfer port and the second right side transfer port are disposed circumferentially symmetrically with respect to the exhaust port.
In a further aspect, the angle about the cylinder axis between the centers of the exhaust port and each of the first left side transfer port and the first right side transfer port is less than 90°, and the angle about the cylinder axis between the centers of the exhaust port and each of the second left side transfer port and the second right side transfer port is greater than 90°.
In another aspect, each of the first right side transfer port and the left side transfer port has a larger surface area than each of the second right side transfer port and the second left side transfer port.
In yet another aspect, the centers of each of the at least one central transfer port and each of the at least two side transfer ports are aligned in a direction parallel to the cylinder axis.
In a further aspect, an internal combustion engine is provided. The engine includes at least one cylinder as described above. A crankcase is connected to the at least one cylinder. An intake port is fluidly connected to the crankcase. A cylinder head is connected to the at least one cylinder. The engine further includes, for each of the at least one cylinder, a piston disposed inside the cylinder and adapted to reciprocate along the cylinder axis. A combustion chamber is defined by the cylinder, the piston and the cylinder head. A fuel injector is fluidly connected to the combustion chamber. A spark plug is disposed at least in part in the combustion chamber. The at least one central transfer port and the at least two side transfer ports selectively connecting the crankcase with the combustion chamber.
In a further aspect, the at least one cylinder comprises at least two adjacent cylinders. The at least two adjacent cylinders are disposed such that their respective cylinder axes are parallel to one another. Lines connecting the centers of the exhaust ports with their corresponding cylinder axes are normal to a plane defined by the cylinder axes of the at least two the adjacent cylinders.
In an additional aspect, a cylinder block for an internal combustion engine includes a crankcase having a central axis and a plurality of cylinders according to any one of the aspects described above. The cylinder axes of the plurality of cylinders defining a plane. The plane contains the central axis of the crankcase. The crankcase is connected to each of the transfer channels corresponding to each of the at least one central transfer port and each of the at least two side transfer ports.
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:
An engine 2, cylinder block 10 and a cylinder 12 for a direct injection, two-stroke, internal combustion engine 2 will be described herein with reference to
The illustrated engine 2 is a 3.4 liter, V6 engine rated for 200 to 300 horsepower. It is however contemplated that aspects of the invention described below could also be used in other types of engines, such as, but not limited to, carbureted or semi-direct injection engines.
Referring to
The cylinder block 10 has a crankcase 14 connected to all six cylinders 12. A crankshaft (not shown) is rotatably disposed inside the crankcase 14 along its central axis 16. The crankshaft extends out through a wall of the crankcase 14 to be operatively connected to an element to be driven by the engine 2, such as a propeller of a watercraft, a wheel of a motorcycle or an endless track of a snowmobile. It is also contemplated that the crankshaft could be connected to the input shaft of a transmission providing gear reduction to a wheel, track, propeller and the like.
The cylinders 12 extend from the crankcase 14 such that a central cylinder axis 18 of each of the six cylinders is perpendicular to the central axis 16 of the crankshaft. The three cylinders 12 of each bank of the V-formation are disposed with their cylinder axes 18 aligned in a common plane 20 which also includes the central axis 16. The three cylinders 12 of the right bank extend on the right side of the crankcase 14 such that the right plane 20 defined by the three cylinders 12 of the right arm is disposed at a block bank angle of 37° with respect to a vertical plane 22 containing the central axis 16. It is contemplated that the block bank angle could be between 25° to 50°. Similarly, three cylinders 12 of the left bank of the V-formation extend on the left side of the crankcase to define a left plane 20 containing the three cylinder axes 18 of the left bank cylinders 12 and disposed at an angle of 30° with respect to the vertical plane 22 containing the central axis 16.
A piston (not shown) is disposed inside each cylinder 12 to reciprocate therein along a reciprocation axis that is coaxial with the cylinder axis 18 of the cylinder 12. Each piston is connected to the crankshaft via a connecting rod (not shown) to drive the crankshaft.
The direction parallel to the cylinder axis 18 for each cylinder 12 will be referred to hereinafter as the axial direction. The upward axial direction is defined as proceeding away from the crankcase 14. The downward axial direction is defined as a direction proceeding toward crankcase 14. The portion of the cylinder 12 further away from the crankcase 14 along the axial direction will be referred to as the upper portion of the cylinder 12, and the portion of the cylinder 12 proximal to the crankcase 14 will be referred to as the lower portion of the cylinder 12.
With reference to
An inlet manifold (not shown), including a throttle body, is connected to the crankcase 14 to supply air for the combustion process.
With reference to
With reference to
As will be described below, each of the central exhaust passage 28, each auxiliary exhaust passage 30, each central transfer channel 32 and each side transfer channel 34 connects to the cylinder 12 through an associated port defined in the cylinder wall 12a.
With reference to
The cylinder wall 12a has defined therein a central exhaust port 58, a pair of auxiliary exhaust ports 60, a right central transfer port 66 and a left central transfer port 66, and a right side transfer port 70 and a left side transfer port 70.
With reference to
The central and auxiliary exhaust ports 58, 60 are generally rectangular in shape with rounded corners. The auxiliary exhaust ports 60 are considerably smaller in size (surface area) than the central exhaust port 58. It is also contemplated that there could be more or less than two auxiliary exhaust ports 60. It is contemplated that the auxiliary exhaust ports 60 could be omitted. It is contemplated that the shapes and sizes of the exhaust port 58 and the auxiliary exhaust ports 60 could be different.
The exhaust manifold 11 is connected to each cylinder 22 via the exhaust passages 28, 30 and exhaust ports 58, 60. An exhaust valve passage 29 (
With reference to
With reference to
With reference to
The side and central transfer ports 66, 70 are generally rectangular in shape and smaller in surface area than the generally rectangular exhaust port 58. The surface area of each central transfer port 66 is smaller than that of the exhaust port 58. The surface area of each side transfer port 70 is smaller than that of the exhaust port 58.
Defining the center 59 of the exhaust port 58 as corresponding to the 0° position with respect to the cylinder axis 18, the angular span of the transfer ports 66, 70 along the circumference of each port 58, 60, 66, 70 can be described with respect to their respective edges extending in the axial direction.
With reference to
Each side transfer port 70 extends from 43° to 115° on their respective sides with respect to the exhaust port center 59. Thus, each side transfer port 70 has an angular span 73 of 72° along the circumference of the cylinder wall 12a between the edges 75, 77. The center 72 of each side transfer port 70 forms an angle of 79° with respect to the exhaust port center 59. It is contemplated that the positions and spans of the side transfer ports 70, the central transfer ports 66 and the bridge formed therebetween could be different than as shown herein.
For ports having a shape other than rectangular, it will be understood that the center of the transfer ports 66, 70 can be defined by the geometric center of the shape. The angular span of the ports is defined by its edges or points located at the largest angle about the cylinder axis 18 with respect to the center of the port.
With reference to
As best seen in
The side walls 36, 38 extend at a non-perpendicular angle from the adjacent cylinder wall 12a. The side wall 38 is connected to the proximal edge 75 of the transfer port 70. The side wall 38 is parallel to the plane 21 defined by the center of the exhaust port 59 and the cylinder axis 18. The side wall 38 extends at an acute angle with respect to the cylinder wall 12a adjacent to the proximal edge 75. The side wall 36 is connected to the distal edge 77 of the transfer port 70. A majority of the side wall 36 is parallel to the plane 21. The side wall 36 has a portion 37, extending to the distal edge 77, that is angled away from the exhaust port 58 toward the central transfer port 66. The angled portion 37 extends at an obtuse angle with respect to the portion of the cylinder wall 12a adjacent to the distal edge 77. The angled portion 37 extends at an acute angle with respect to a chord 70c joining the edges 75, 77 of the transfer port 70.
In the plane normal to the cylinder axis 18, the distal edge 77 of the transfer port 70 and the rear wall 40 are disposed on opposite sides of the proximal edge 75 of the transfer port 70. The length of the side wall 36 including the portion 37 is greater than the length of the chord 70c.
In the plane normal to the cylinder axis 18, the length 70a of the transfer channel 34 can be defined as the distance between the rear wall 40 and the distal edge 77 of the transfer port 70 in the direction parallel to the plane 21, the side wall 38 and the side wall 36 excluding the angled portion 37. If the side walls 36, 38 are not parallel to the plane 21, the length of the transfer channel 34 in the plane normal to the cylinder axis 18 is measured in the direction parallel to the mutually parallel portions of the side wall 38 and the side wall 36 excluding the angled portion 37. As can be seen in
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With reference to
With reference to
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As the piston (not shown) reciprocates in the cylinder 22, it opens and closes the central and side transfer ports 66, 70, the exhaust ports 58, 60, and the pair of auxiliary exhaust ports 60, in a manner commonly known in two-stroke internal combustion engines. When the piston is disposed in the upper portion of the cylinder 22, the lower ports 67, 71 are open, and the transfer ports 66, 70 and exhaust ports 58, 60 are closed so that air from the crankcase fills the lower portion of the cylinder 12. As the piston descends towards the crankcase 14, it first travels past the exhaust ports 58, 60 and then the transfer ports 66, 70 to open them in that order. Air from the lower portion of the cylinder 12 is thereby allowed to flow into combustion chamber 23 to mix with the fuel injected therein. Some of the unburnt fuel remaining in the combustion chamber 23 after the previous combustion cycle is pushed out into the exhaust passage 28. When the piston moves upwards towards the combustion chamber 23, the air therein is compressed and exhaust gases are expelled out of the exhaust ports 58, 60. Air is prevented from flowing out through the transfer channels 32, 34 by a one-way valve such as a reed valve disposed in the air intake manifold through which air is delivered to crankcase 14 and the transfer channels 32, 34.
This design of the transfer ports 66, 70 and the transfer channels 32, 34 described above helps to balance the competing goals of minimizing fuel lost from the exhaust port and optimizing mixture of the fuel injected into the combustion chamber 23 by the fuel injector 26 and air flowing into the combustion chamber 23 from the crankcase 14.
Turning now to
The cylinder 12′ has a single central transfer port 66 on the cylinder wall 12a opposite the exhaust port 58. The cylinder 12 has two side transfer ports 80, 82 defined on each side of the cylinder wall 12a between the exhaust port 58 and the central transfer port 66.
The single central transfer port 66 in the upper portion of the cylinder 12 is connected to the port 67 in the lower portion of the cylinder 12′ via a central transfer channel 32. The central transfer port 66 is defined on the cylinder wall 12a opposite to the exhaust port 58. The cylinder axis 18 is disposed between the center 59 of the exhaust port 58 and the center 68 of the central transfer port 66. The center 68 of the central transfer port 66 is thus disposed in the plane 21. The single central transfer channel 32 is defined by two side walls 46, a rear wall 48, and an upper wall 50 and is similar to each of the two central transfer channels 32 of the cylinder 12′. The side walls 46 extend from the periphery of the central transfer port 66. The side walls 46 are parallel to each other and to the plane 21. The rear wall 48, extending between the side walls 46, is curved and coaxial with the cylinder axis 18. The upper wall 50 extends between the side walls 46, from the upper edge of the central transfer port 66 to the rear wall 48. The plane 21 passes through the rear wall 48 and the upper wall 50. The upper wall 50 extends at a non-normal angle to the cylinder axis 18 and the cylinder wall 12a. The upper wall 50 extends from the rear wall 48 of the central transfer port 66 toward the upper edge of the central transfer port 66 at an acute angle to the axially upward direction. The central transfer channel 32 thus directs air into the cylinder 12′ upwards towards the exhaust port 58 on the cylinder wall 12a opposite thereto.
Each first side transfer port 80 is closer to the exhaust port 58 than the second side transfer port 82 on that side. A side transfer channel 84 connects the side transfer port 80 in the upper portion of the cylinder 12 with a port 81 in the lower portion of the cylinder 12. The transfer channel 84 has two side walls 90, 92 extending from the axial edges of the transfer port 80. The side wall 90 is parallel to the plane 21 defined by the exhaust port 58 and the cylinder axis 18. The side wall 90 has a portion 91 adjacent to the side transfer port 80 which extends normal to the plane 21. A rear wall 94 extends between the side walls 90, 92 which converge towards one another as they extend away from the side transfer port 80. An upper wall 93 extends perpendicularly to the cylinder axis 18 between the walls 90, 92, 94 and the side transfer port 80.
Each second side transfer port 82 is farther from the exhaust port 58, disposed between the corresponding first side transfer port 80 of that side and the central transfer port 66. A side transfer channel 86 connects the side transfer port 82 in the upper portion of the cylinder 12 with a port 87 in the lower portion of the cylinder 12. The transfer channel 86 has two side walls 96, 98 extending from the axial edges of the transfer port 82. The side walls 96, 98 are parallel to one another and perpendicular to the plane 21. A rear wall 97 extends between the parallel side walls 96, 98. An upper wall 99 extends perpendicularly to the cylinder axis 18 between the walls 96, 97, 98 and the side transfer port 82.
With reference to
Each first side transfer port 80 has an angular span 85 along the cylinder wall of 47°, extending from 47° to 94° on their respective sides with respect to the exhaust port center 59. Each second side transfer port has an angular span 83 along the cylinder wall of 39°, extending from 110° to 149° on their respective sides with respect to the exhaust port center 59.
The transfer ports 66, 80, 82, and the transfer channels 32, 84, 86 of the cylinder 12′ are configured to optimize mixing of fuel and air in the combustion chamber 23, the fuel and air being respectively delivered therein from the fuel injector 27 and the crankcase 14.
With reference to
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 Unites States Provisional Application No. 61/713,742 filed on Oct. 15, 2012, the entirety of which is incorporated herein by reference.
Number | Date | Country | |
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61713742 | Oct 2012 | US |