This invention is related to the field of internal combustion engines and more specifically to improvements in such engines configured with opposing cylinders and opposing pistons in each cylinder (“OPOC engine”).
This invention involves improvements to internal combustion engines and in particular OPOC engines of the type described and claimed in earlier U.S. Pat. Nos. 6,170,443, and 7,434,550, which are incorporated herein by reference. Other types of OPOC engines having one or more crankshafts, also can benefit from the present invention.
As background, the OPOC engine from U.S. Pat. No. 6,170,443 is shown in
The inner piston 120 of the left cylinder 100 is connected to crankshaft eccentric 312 by means of pushrod 412; the inner piston 220 of the right cylinder 200 is similarly connected to crankshaft eccentric 322 by pushrod 422. During normal engine operation, pushrods 412 and 422 are always under compression. The pushrods have concave ends 413 and 423 which ride on convex cylindrical surfaces 125 and 225 on the rear of the inner pistons.
The outer piston 110 of the left cylinder 100 (1100) is connected to crankshaft eccentric 311 by means of pullrod 411 (1411); the outer piston 210 of the right cylinder 200 (1200) is similarly connected to crankshaft eccentric 321 by pullrod 421 (1421). During normal engine operation, pullrods 411 (1411) and 421 (1421) are always under tension. While single pullrods are shown on the near side in
The four pistons 110, 120, 210, and 220 have a plurality of piston rings 112, 122, 212, and 222, respectively, located behind the combustion faces. Additional piston rings may be added to the piston skirts, as may be required to reduce wear and control lubrication oil distribution. The cylinders 100 and 200 each have intake, exhaust, and fuel injection ports. On the left cylinder 100, the outer piston 110 opens and closes intake ports 161 (intake piston) and the inner piston 120 opens and closes exhaust ports 163 (exhaust piston). Fuel injection port 162 is located near the center of the cylinder. On the right cylinder 200, the inner piston 220 opens and closes intake ports 261 and the outer piston opens and closes exhaust ports 263. Again, fuel injection port 262 is located near the center of the cylinder. The asymmetric arrangement of the exhaust and intake ports on the two cylinders serves to help dynamically balance the engine, as described below.
Each of the four crankshaft eccentrics 311, 312, 321, and 322 are positioned with respect to the crankshaft rotational axis 310. The eccentrics for the inner pistons 312, 322 are further from the crankshaft rotational axis than the eccentrics for the outer pistons 311, 321, resulting in greater travel for the inner pistons than for the outer pistons. The eccentrics for the inner left piston 312 and the outer right piston 321, the pistons which open and close the exhaust ports in the two cylinders, are angularly advanced, while the eccentrics for the outer left piston 311 and inner right piston 322 are angularly retarded (note that the direction of crankshaft rotation is counterclockwise, as indicated by the arrow in
As further shown in
As mentioned above, the pullrods are always under tension forces Fr that are communicated to and from the piston (via piston pins) as compression forces Fp. During the times that the pullrods are at an angle with respect to the reciprocating axis of the outer pistons, there are minor side force components Fs generated at the outer piston pins 114 (1114) and 214 (1214). These side forces occur during both the power and compression strokes of the engine cycle and are directed towards the cylinder walls. Several efforts have been made to minimize the effects of such side forces, including increasing the lubrication between the cylinder wall and the piston skirt; providing more piston rings along the piston skirt; and reducing the length of the piston skirt. However, each conventional attempt to reduce the effects of pullrod side forces has resulted in other undesirable effects.
The present invention provides reduction in the side forces attributed to pullrod connections to the outer pistons of an OPOC engine by providing an intermediate bridge member between the pullrods and the outer piston to dissipate the side forces and isolate them from reaching the outer piston.
The present invention provides reduction in the side forces attributed to pullrod connections to the outer pistons of an OPOC engine by providing an intermediate bridge member with articulated low friction connections to the pullrods and the outer piston.
The present invention provides reduction in the side forces attributed to pullrod connections to the outer pistons of the OPOC engine by providing an extension to the cylinder housing with a pair of elongated side openings with lubricated guide edge bearing surfaces for allowing an intermediate bridge member between the pullrods and the outer pistons to slide there-along during engine operation to dissipate the side forces and isolate them from reaching the outer piston.
The present invention provides reduction in the side forces attributed to pullrod connections to the outer pistons of the OPOC engine by providing a low friction and rotatable bearing connection between the pullrods and the intermediate bridge member that is located between the pullrods and the outer piston.
The present invention provides reduction in the side forces attributed to pullrod connections to the outer pistons of the OPOC engine by providing a ball joint connection between the intermediate bridge member and the outer piston.
Two embodiments of the intermediate bridge element are shown. In a first embodiment, the bridge element contains a pair of upper and lower wear pads that contact the lubricated guide edge bearing surfaces provided by the extension to the cylinder housing. In a second embodiment, the upper and lower surfaces of the intermediate bridge element are used to directly contact and slide along the lubricated guide edge bearing surfaces provided by the extension to the cylinder housing.
It is an object of the present invention to provide an improved OPOC engine with reduced friction and increased efficiencies by eliminating side forces on the outer pistons during the engine cycle.
It is another object of the present invention to provide an improved OPOC engine in which the connections between the outer pistons and their associated pull rods do not allow the communication of off-axis side forces to either element.
The present invention is shown in
The improvement over the prior art OPOC engine described above results from the use of a guided bridge 800 that is located between the outer piston 510 and the pullrods 511a and 511b. (Although the following discussion is directed to the left cylinder 500, it should be understood that the right cylinder is identically configured to provide identical improvements to the engine as a whole.)
Guided bridge 800 is mounted for reciprocating movement in an extension cap 902 that connects to and forms part of engine housing 900. Guided bridge 800, in this embodiment, (see
Guided bridge 800 is mounted for reciprocating movement in an extension cap 902 that connects to and form a part of engine housing 900. Guided bridge 800, in this embodiment, (see
The base 801 of the triangular shaped guided bridge 800 has bosses 803a and 803b that extend outwardly along a horizontal axis “A-A” that is perpendicular to the cylinder axis. Bosses 803a and 803b fit within the races of needle bearings 514a and 514b (
While the embodiment above is described as having guided bridge face surfaces to guide face surfaces as being smoothly ground or polished metal surfaces, it is because such surfaces can be formed very economically with significantly improved results compared to the prior art. However, it is appreciated that other low friction alloy, ceramic or plastic materials could be implanted into the opposing surfaces to have sliding surface contact if their low friction properties are suitable for improvements in this environment.
Outer piston 510 (
Outer piston 510 (
When the pistons of left cylinder 500 enter their power stoke of the engine cycle, the expanding gases present on the face of piston 510 force the ball socket 512 against the bridge nose 802. Due to the interaction of the bosses 803a and 803b with the bearings 514a and 514b, and the resistance of the angled pull rods 511a and 511b, any side forces that are generated are directed between upper and lower surfaces 804/806 and 808/810 of guided bridge 800 to the corresponding lower and upper guide surfaces 904/906 and 908/910 while guided bridge 800 is sliding there along. As a result, almost all pullrod generated side forces are dissipated so as not to be fed back and effect the travel of outer piston 510.
When the pistons of left cylinder 500 enter their compression stoke of the engine cycle, pull rods 511a and 511b are again under tension and being pulled by the crank shaft 700. Pull rods 511a and 511b interact with guided bridge 800 through bearings 514a and 514b and bosses 803a and 803b to force the bridge nose 802 against socket 512. This action causes outer piston 510 to be pushed along the cylinder axis towards inner piston 520 against the resistance of air being compressed within the cylinder. Due to the interaction of the angled pull rods 511a and 511b through bearings 514a and 514b with bosses 803a and 803b and the resistance of outer piston 510, any side forces that are generated are directed between the upper and lower surfaces 804/806 and 808/810 of the guided bridge 800 to the corresponding lower and upper guide surfaces 904/906 and 908/910 while guided bridge 800 is sliding there along. Consequently almost all pullrod generated side forces are isolated from outer piston 510. As stated earlier, the reduction in side forces on the pistons of an internal combustion engine is highly desirable in order to reduce piston chafing or scuffing that may sometimes occur during operating conditions.
The function of the spherical bearing is illustrated with respect to the vector graphs of
In
In contrast,
The embodiment shown and described herein is merely exemplary of various configurations that may be designed to exhibit the inventive concepts recited in the claims and is not intended to be restrictive.
This application claims priority benefit of provisional application Ser. No. 61/209,904, filed Mar. 12, 2009.
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Number | Date | Country | |
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Number | Date | Country | |
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61209904 | Mar 2009 | US |