The field includes constructions for thermal management in opposed-piston engines in which a combustion chamber is defined between end surfaces of pistons disposed in opposition in the bore of a cylinder. More particularly, the field includes opposed-piston engines with combustion chambers that minimize heat loss from the combustion chamber to other parts of the engine.
The related patent applications describe two-stroke cycle, compression-ignition, uniflow-scavenged, opposed-piston engines in which pairs of pistons move in opposition in the bores of ported cylinders. A two-stroke cycle opposed-piston engine completes a cycle of engine operation with two strokes of a pair of opposed pistons. During a compression stroke, as the pistons begin to move toward each other, charge air is admitted into the cylinder, between the end surfaces of the pistons. As the pistons approach respective top dead center (“TDC”) locations to form a combustion chamber the charge air is increasingly compressed between the approaching end surfaces. When the end surfaces are closest to each other, near the end of the compression stroke, a minimum combustion chamber volume (“minimum volume”) occurs. Fuel injected directly into the cylinder mixes with the compressed charge air. Combustion is initiated when the compressed air reaches temperature and pressure levels that cause the fuel to begin to burn; this is called “compression ignition”. Combustion timing is frequently referenced to minimum volume. In some instances, injection occurs at or near minimum volume; in other instances, injection may occur before minimum volume. In any case, in response to combustion the pistons reverse direction and move away from each other in a power stroke. During a power stroke, the pistons move toward bottom dead center (“BDC”) locations in the bore. As the pistons reciprocate between top and bottom dead center locations they open and close ports formed in respective intake and exhaust locations of the cylinder in timed sequences that control the flow of charge air into, and exhaust from, the cylinder.
In order to maximize the conversion of the energy released by combustion into motion, it is desirable to prevent heat from being conducted away from the combustion chamber through the piston. Reduction of heat lost through the piston increases the engine's operating efficiency. Typically, heat transfer through the piston is reduced or blocked by insulating the piston crown from the body of the piston. However, it is also the case that retention of the heat of combustion at the end surface of the piston can cause thermal damage to the piston crown and nearby piston elements.
Piston thermal management is a constant concern, especially given the ever-increasing loads expected from modern internal combustion engines. In a typical piston, at least four areas are of concern for thermal management: the piston crown, the ring grooves, the piston under-crown, and the piston/wristpin interface. The piston crown can be damaged by oxidation if its temperature rises above the oxidation temperature of the materials of which it is made. Mechanical failure of piston elements can result from thermally-induced material changes. The rings, ring grooves, and the lands that border the ring grooves can suffer from carbon build-up caused by oil heated above the coking temperature. As with the ring grooves, the under surface of the piston crown can also suffer from oil coking.
A recent study indicates that an opposed-piston engine two-stroke cycle engine exhibits increased thermal efficiency when compared with a conventional six-cylinder four-cycle engine. (Herold, R., Wahl, M., Regner, G., Lemke, J. et al., “Thermodynamic Benefits of Opposed-Piston Two-Stroke Engines,” SAE Technical Paper 2011-01-2216, 2011, doi:10.4271/2011-01-2216.) The opposed-piston engine achieves thermodynamic benefits by virtue of a combination of three effects: reduced heat transfer due to a more favorable combustion chamber area/volume ratio, increased ratio of specific heats from leaner operating conditions made possible by the two-stroke cycle, and decreased combustion duration achievable at the fixed maximum pressure rise rate arising from the lower energy release density of the two-stroke engine. With two pistons per cylinder, an opposed-piston engine can realize additional thermodynamic benefits with enhanced piston thermal management.
Enhanced thermal management of the pistons of an opposed-piston engine is realized by provision, in each piston of a pair of opposed pistons, of piston crowns made of two or more layers of different materials. The pistons with multiple layers described herein reduce the transfer of heat from the combustion chamber and piston crown to the piston body, while at the same time reducing or preventing thermal damage to the rings and coking of lubricant in the ring grooves.
In some implementations, a piston crown of a piston of a pair of pistons of an opposed-piston engine includes a barrier layer at the piston end surface and a conductive layer adjacent to the barrier layer, in which the barrier layer contacts the fuel and air during combustion while the conductive layer connects the barrier layer to the piston skirt and other piston components.
In a related aspect, a method is provided for making a piston crown of a piston of a pair of pistons of an opposed-piston engine that includes a barrier layer at the piston end surface and a conductive layer adjacent to the barrier layer, in which the barrier layer contacts the fuel and air during combustion while the conductive layer connects the barrier layer to the piston skirt and other piston components.
Fuel injection nozzles 17 are secured in threaded holes that open through the side surface of the cylinder. Two pistons 20, 22 are disposed in the bore 12 with their end surfaces 20e, 22e in opposition to each other. For convenience, the piston 20 is referred to as the “intake” piston because of its proximity to the intake port 14. Similarly, the piston 22 is referred to as the “exhaust” piston because of its proximity to the exhaust port 16. Preferably, but not necessarily, the intake piston 20 and all other intake pistons in the opposed-piston engine are coupled to a crankshaft 30 disposed along one side of the engine 8; and, the exhaust piston 22 and all other exhaust pistons are coupled to a crankshaft 32 disposed along the opposite side of the engine 8.
Operation of an opposed-piston engine such as the engine 8 with one or more ported cylinders (cylinders with intake and exhaust ports formed near ends thereof) such as the cylinder 10 is well understood. In this regard, in response to combustion the opposed pistons move away from respective TDC positions where they are at their innermost positions in the cylinder 10. While moving from TDC, the pistons keep their associated ports closed until they approach respective BDC positions where they are at their outermost positions in the cylinder and the associated ports are open. The pistons may move in phase so that the intake and exhaust ports 14, 16 open and close in unison. Alternatively, one piston may lead the other in phase, in which case the intake and exhaust ports have different opening and closing times.
As charge air enters the cylinder 10 through the intake port 14, the shapes of the intake port openings cause the charge air to rotate in a vortex 34 about the cylinder's longitudinal axis, which spirals in the direction of the exhaust port 16. A swirl vortex 34 promotes air/fuel mixing, combustion, and suppression of pollutants. Swirl velocity increases as the end surfaces 20e and 22e move together.
With reference to
The longitudinal diametric sectional view of a combustion chamber seen in
In the sectional view of
The barrier layer 102A includes flat portions of the end surface 108C, the concave bowl 120A, the pair of notches, and a sidewall 505. In this piston crown 500, the barrier layer 102A forms part of the walls of the combustion chamber (150 in
The conductive layer 102B includes features similar to those of the barrier layer 102A, including flat portions 108D, a pair of notches 118, a concave bowl 120B, and a sidewall 510. The dimensions of the features allow for a tight fitting between the barrier layer 102A and the conductive layer 102B. The conductive layer 102B quickly transports and dissipates heat away from the piston crown. The barrier layer 102A protects the conductive layer 102B from the high temperatures of the combustion chamber, so that the conductive layer and other parts of the piston will not suffer from: oxidization, loss in strength, or over-heating of any lubricant in contact with the piston. Materials conventionally used for engine pistons are suitable for use in the conductive layer 102B. For example, the conductive layer 102B can be made of steel, stainless steel, cast iron, aluminum, aluminum alloys, magnesium, magnesium alloys, and the like. The materials used for the conductive layer 102B have thermal conductivity values of 25 W/m·° C. or more.
Like the barrier layer 102A, the conductive layer 102B can be made by additive manufacturing, forging, casting, magnetic pulse forming, machining, and the like, or any suitable combination of these methods. The thickness of the portion of the conductive layer 102B that supports the combustion chamber, the bowl 120B, will depend on the material properties of the conductive layer 102B and the overall size of the piston. For example, for a 98 mm diameter piston, the thickness of the conductive layer as described above would be about 3.5 mm, and for a 130 mm diameter piston, a conductive layer would have a thickness as described above of about 5 mm. The thickness of the conductive layer may vary across the layer, so that the thickness of the conductive layer is non-uniform.
The fitting between the back side of the barrier layer and the top of the conductive layer may generally be a tight fitting, but in some implementations, areas where the two layers do not contact may exist. These areas where the barrier and conductive layers do not contact, or voids, may be filled with gas or may be evacuated. The location and dimensions of these voids vary with the materials used for the barrier and conductive layers, as well as the configuration of the features of the piston crown. Voids, in conjunction with variations in thickness of the barrier and conductive layers, can be used to regulate uniformity of the temperature of the combustion chamber. The location of voids can reduce the temperature difference between hot spots and cold spots or areas of average temperature in the combustion chamber. Possible locations of voids include areas under the junction of the bowl 120A with flat portions of the end surface of the piston crown and areas under the notches 118. The voids can vary in size, as well as location. In height, voids can be a third (⅓) or less of the thickness of the barrier layer 102A. Alternatively, voids can be a half (½) or less of the thickness of the barrier layer 102A.
To form a single piston crown 500 from the barrier layer 102A and the conductive layer 102B, a method of joining the layers can be selected to suit the materials of the layers. The layers can be joined in forming, for example through additive manufacturing. Additive manufacturing can include casting a first layer, one of the barrier or conductive layers, then casting the other layer on the first layer, or casting a first layer then adding powdered metal to create the second layer that is sintered or heat treated to form the unitary piston crown. Adhesive or joining methods can be used to form a single piston crown from the barrier and conductive layers. Such joining methods can include welding along the side walls using electron beam welding, laser welding, magnetic pulse forming/welding, or impulse welding techniques. Further, any other suitable joining technique can be used to make a single piston crown 500 from a barrier layer 102A and conductive layer 102B. In some implementations, the joining technique can join the barrier layer 102A and conductive layer 102B along the sidewalls 505, 510 so that there may be a discontinuity between the layers 102A and 102B in the interior of the crown to form the voids described above. In the voids there may be a vacuum or air when the layers are joined using welding or other adhesive joining methods. When additive manufacturing, such as casting and overcasting, are used to form the barrier layer 102A and conductive layer 102B, the void can be filled with a foamed material instead of gas or instead of being evacuated.
As with the two-layered piston crown, described above, the three layers of the piston crown 700 can be joined using any suitable fabrication technique, including additive manufacturing or welding. When using an additive manufacturing technique, the layers, though described above as discrete layers, may have interfaces in which the materials of the adjacent layers mix or interact. Conversely, in implementations where the layers of the piston crown 700 are joined by welding along sidewalls 505 and 510, adjacent layers may have discontinuities or gaps between the layers.
In some implementations, the piston crown is formed by casting and over casting. In this type of fabrication, the first layer cast is the barrier layer. The insulating layer is formed separately, for example by 3D printing or slipcasting. A second layer, the conductive layer, is cast over the first layer with the insulating layer inserted between the first and second layers. When the types of material used require, the conductive layer can be the first layer cast and the barrier layer can be the second layer cast, with the insulating layer inserted between the first and second layer during fabrication.
Though the multi-layered piston crown described herein is described with respect to piston crowns with a particular configuration of bowl and combustion chamber, the multi-layered structure of the crown with a barrier layer and conductive layer can be used with bowls and combustion chambers of any configuration, including those with rotational symmetry or a different, asymmetric configuration than that shown and described herein. Further, though each layer (e.g., barrier layer, conductive layer, insulating layer) is described as a discrete layer of one material, in some implementations, each layer may include more than one material either as a composite of a matrix material and a reinforcing material, a solid solution of materials, or as multiple layers of different materials.
The scope of patent protection afforded the novel tools and methods described and illustrated herein may suitably comprise, consist of, or consist essentially of a piston crown with two or more layers, in which the layers include at least a barrier layer and a conductive layer and the methods of fabricating such a piston crown. Further, the novel tools and methods disclosed and illustrated herein may suitably be practiced in the absence of any element or step which is not specifically disclosed in the specification, illustrated in the drawings, and/or exemplified in the embodiments of this application. Moreover, although the invention has been described with reference to the presently preferred embodiment, it should be understood that various modifications can be made without departing from the spirit of the invention. Accordingly, the invention is limited only by the following claims. Further, the scope of the novel piston crown described and illustrated herein may suitably comprise, consist of, or consist essentially of the elements two or more layers, in which the layers include at least a barrier layer and a conductive layer and the methods of fabricating such layers and the resulting piston crown. The novel piston crown disclosed and illustrated herein may suitably be practiced in the absence of any element which is not specifically disclosed in the specification, illustrated in the drawings, and/or exemplified in the embodiments of this application.
This Application is a continuation of U.S. patent application Ser. No. 15/056,909, titled “Multi-Layered Piston Crown for Opposed-Piston Engines,” filed Feb. 29, 2016, now U.S. Pat. No. 10,119,493. This Application contains subject matter related to the subject matter of the following commonly-owned patent applications: U.S. patent application Ser. No. 14/815,747, filed on Jul. 31, 2015, now U.S. Pat. No. 9,840,965; and U.S. patent application Ser. No. 13/891,523, filed on May 10, 2013, now U.S. Pat. No. 9,464,592.
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Child | 16178966 | US |