This invention relates to internal combustion engines, especially to internal combustion engines that can be used in mobile vehicles, including, but not limited to, automobiles, aircraft and boats. This invention also relates to internal combustion engines in which multiple pistons are joined as part of a rigid subassembly.
A four cylinder horizontally opposed “Flat Four” or “Boxer” engine includes four cylinders, which are mounted horizontally in opposed pairs. The term “Boxer Engine” describes the motion of the four pistons as they move back and forth in opposing pairs, much like a boxer's arms. This engine was first introduced in the late 1930's. The horizontally opposed layout of the cylinders helped to balance out the forces exerted on the crankshaft by the moving pistons and the connecting rods, which connected each individual piston to a centrally mounted crankshaft. Although pistons were located on opposite sides of a central crankshaft, opposed pistons did not move along the same axis, and the four pistons moved along four parallel axes, which intersect the crankshaft at different lateral positions. Unlike the present invention, each of the pistons comprised a separate member with its own connecting rod, which moves angularly relative to both the crankshaft and the piston.
U.S. Pat. No. 6,082,314 discloses another type of opposed cylinder internal combustion engine. In this patent four cylinders are arranged in an H-shaped configuration. Two double acting or double-ended pistons, each with generally cylindrically shaped crowns on opposite sides of flat rectangular parallelepiped middle sections, are mounted on a crank shaft so that each double acting piston reciprocates in opposed cylinders. The two double acting pistons, each of which is part of a one-piece member with piston crowns at either end, move in the same direction during each stroke, and circular slide blocks, eccentrically mounted on the crank shaft, are received in openings between the piston crowns to replace connecting rods. A dynamic balance slide piece reciprocates along an axis perpendicular to the piston reciprocation. The SYTEC engine proposed by CMC Research House at the Department of Mechanical & Manufacturing Engineering of the University of Melbourne also includes a bearing block that moves perpendicular to the motion of two double-ended, single piece pistons connected to a central crankshaft.
U.S. Pat. No. 2,370,902 also discloses multiple sets of double-ended pistons that move in the same direction during each stroke. In this case, connecting rods rigidly connected to pistons at opposite ends are themselves interconnected by a cross bar. Anti-friction rollers mounted on a slide bar secured to the cross bar move with the double ended pistons and engage cams in the form of star shaped plates to impart rotation to a drive shaft.
In U.S. Pat. No. 4,011,842, a pair of spaced parallel, double-ended cylinders straddle a crankshaft and two double-ended pistons are connected to the crankshaft by a T-shaped connecting member so that linear motion of the double-ended pistons causes rotation of the crankshaft. The two doubled-ended pistons move in opposite directions. U.S. Pat. No. 6,446,587 and U.S. Pat. No. 6,073,595 are other examples of internal combustion engines with double-ended pistons moving in opposite directions.
It has been suggested that internal combustion engines with double-ended pistons can also be used to produce an electrical current. In U.S. Pat. No. 6,532,916 an oscillating alternator coil attached to a moving double-ended piston in an internal combustion engine moves through a magnetic field imparted by a stationary magnet. In some small internal combustion engines and alternator often comprises a ring of magnets mounted on a rotating flywheel, which act in conjunction with stationary core and windings on the engine body. Two examples of such devices are shown in U.S. Pat. No. 3,828,212 and U.S. Pat. No. 4,101,371.
The instant invention is believed to include many of the advantageous features represented by these examples of the prior art, but achieves these improvements by employing a configuration in which the components are easier to fabricate and in which assembly is simpler. The instant invention should therefore be easier to service since assembly and disassembly are more straightforward. The anticipated life and reliability of the engine constructed according to this invention should also be significantly greater than has heretofore been possible with more elaborate engine configurations. Relative movement of component parts of this engine is believed to place less stress on moving parts, and these moving parts can be lubricated more efficiently and more effectively. The efficiency that can be achieved with this inventive configuration is also believed to be superior to that which can be achieved with conventional internal combustion engine configurations. In view of the simplicity of the basic operation of this engine, excessive vibration should not be a problem. In spite of the effort that has been expended to improve the performance of conventional internal combustion engine configurations, the piston slide body configuration of the instant invention should offer these and other advantages over these and other prior art configurations.
According to one aspect of this invention, an internal combustion engine can include the following components. A housing encloses a compartment with opposed cylinders at opposite ends of the compartment for receiving pistons. The pistons are on a slide body reciprocal in the housing compartment. The slide body has pistons at opposite ends of the slide body. Individual pistons are received within individual cylinders. Cyclical combustion within the cylinders imparts linear reciprocal motion to the slide body. A rotating disk, which can be a flywheel, is positioned in the housing compartment. The rotating disk is located adjacent to the slide body and is rotatable about an axis generally perpendicular to linear reciprocal movement of the slide body. Interengaging members on the slide body and rotating disk sufficiently laterally offset from the axis of rotation of the rotating disk impart rotary motion to the rotating disk as the slide body linearly reciprocates within the housing compartment. The assembly also includes a drive shaft extending through the housing. Rotation of the rotating disk is transmitted to the drive shaft so that linear motion of the slide piston is transmitted through the rotating disk to the drive shaft for delivering external power.
According to another aspect of this invention an internal combustion engine includes the following. Reciprocal pistons engage a rotary member to transfer linear motion of the pistons to rotary motion, the pistons being mounted in a housing including the following housing components. The engine includes an upper cover and a separate lower cover. Side plates are attachable to and detachable from the upper cover and the lower cover adjacent opposite edges thereof to form a central housing subassembly having a generally rectangular cross section. A cylinder body can be attached to and detachable from one end of the central housing subassembly, the cylinder body including cylinders receiving the reciprocal pistons. A head and valve subassembly is attachable to and detachable from the cylinder body and encloses one end of the cylinders. This internal combustion engine can be assembled and disassembled by respectively attaching and detaching the housing components in surrounding relationship to the reciprocal pistons and the rotary member.
According to still another aspect of this invention, a piston subassembly for use in an internal combustion engine includes a central body including at least one arm extending from each end of the central body. The piston subassembly also includes cylindrical pistons on the distal ends of each arm, the central body, the arms and the cylindrical pistons comprising a rigid body such that as the piston subassembly moves through a complete cycle, and no relative angular movement of the cylindrical pistons, the arms and the central body occurs. The piston subassembly also includes an engagement surface on the central body, which engages a separate member during linear movement of the piston subassembly to impart rotary movement to the separate member to output energy due to combustion in the internal combustion engine.
According to a fourth aspect of this invention, an internal combustion engine includes an electrical generator, which comprises a flywheel located within a nonferromagnetic engine housing. The flywheel has a number of magnets attached thereto to increase the inertia of the flywheel and a plurality of electrical conductors located on the exterior of the nonferromagnetic engine housing. Rotation of the flywheel relative to the electrical conductors generates an electrical current in the electrical conductors.
According to another aspect of this invention, an internal combustion engine includes a plurality of linearly reciprocal pistons, all of the pistons moving in the same direction during each stroke. The internal combustion engine also includes a flywheel having an axis of rotation substantially perpendicular to the direction in which the pistons move. The flywheel has sufficient angular momentum to dampen reaction forces acting in a direction opposite from the direction of movement of the pistons during sequential strokes due to the expansion of a combustible fuel-air mixture sequentially acting on individual pistons so that the internal combustion engine can be employed in a mobile vehicle, such as an automobile or other motor vehicle, and airplane, a lawnmower, off the road vehicles, and in many other applications.
A linear gear bearing can also be used to prevent any bureau drawer effect as the slide body piston reciprocates.
Although not limited to a four stroke, two cycle internal combustion cycle, this invention will be described in terms of this representative configuration. It should be understood that the basic invention can be adapted to other internal combustion cycles by one of ordinary skill in the art and that this invention can be implemented as different configurations, which would be apparent to one of ordinary skill in the art. Some aspects of this invention are also suitable for use with apparatus other than an internal combustion engine.
The preferred embodiment of the internal combustion engine 1 according to this invention has two primary internal moving parts located within a housing to deliver the power generated by the combustion of an air fuel mixture. These internal moving parts are a slide body 50, which reciprocates in a straight line, and a rotating disk, which preferably is in the form of a flywheel 70. Both the slide body 50 and the rotating disk or flywheel 70, are located within the same compartment 36 formed by a main housing 10. The slide body 50 includes a plurality of pistons 56A-D and the rotating disk or flywheel 70 is connected to an external drive shaft 74. In the preferred embodiment, linear movement of the slide body 50 is transmitted to the flywheel 70 by engagement of a slide bearing or pin 72 located on the flywheel 70 with a track 62 located on the slide body 50.
Valves 92 and means for operating the valves are located in a valve-cam subassembly located at the ends of the main housing 10. In the preferred embodiment an external valve shaft 100 is rotated in response to linear movement of the slide body 50. The engine 1 can be carbureted or fuel injected. The engine 1 is cooled by an external electric water pump, which moves coolants throughout the engine 1. External mechanical oil and water pumps can also be used.
The basic operation of a two stoke, four cycle engine in accordance with this invention can be understood with reference to
The main housing 10 includes four main interlocked walls or parts 16, 20, 24, 26 that can be fitted together with a minimum number of fasteners to simplify assembly and disassembly of the engine 1. One advantage of this engine is that the need for a majority of the head gaskets in conventional engines is eliminated and mating parts of this engine can be sealed with liquid sealants, such as silicone These four interlocked parts 16, 20, 24, 26 surround the main housing compartment 36 in which the slide body 50 and the flywheel 70 are located. Two cylinder bodies 40A and 40B are located at opposite ends of the main compartment 36. A plurality of side by side cylinders 42A-D communicate with the main housing compartment 36. These cylinders 42A-D extend through the cylinder bodies 40A and 40B, to the heads 90A and 90B, in which intake and outlet ports 113A and 113B for each cylinder are located, close the ends of the cylinders 42A-D. The mechanisms for opening and closing the valves are also located on these valve-cam plates 98. In the preferred embodiment, valve-cam gears 94 driven by the external valve shaft 100 are located on the valve plates 98.
In the preferred embodiment, multiple pistons are located on each end of the slide body. These pistons are rigidly connected as part of the slide body, and the pistons reciprocate within the cylinders without side forces between the pistons and the cylinders, thus causing only even, circular wear on the cylinders. The slide body includes a central body, which reciprocates along a tongue and grooved or bearing tract relative to the housing side plates to insure that the slide body moves linearly without any significant angular movement. The housing 10 and other components will be discussed in greater detail after a more thorough description of the primary moving parts that translate the combustion of a fuel air mixture into usable external power.
Combustion of fuel-air mixture in the cylinders 42A-D causes expansion of the gas and forces the pistons 56A-D outward during this expansion stroke. The preferred embodiment is intended for use in a standard four cycle, two stroke engine, although the basic invention can be employed for two stroke engines, for Diesel engines or for other conventional internal combustion engine cycles.
The first embodiment of this invention includes four cylindrical, reciprocal pistons 56A-D, two of which are located on each end of the slide body or slide body piston subassembly 50. This invention is not limited to a four cylinder configuration and other configurations, and their characteristics, will be discussed in more detail after describing the representatives four cylinder embodiments. The pistons 56A-D are joined to the slide central body portion 60 by piston arms 54. Piston arms 54 do not comprise a linkage permitting relative movement between the pistons 56A-D and the central body portion 60 in the sense in which connecting rods form a movable linkage between pistons and the crankshaft of a conventional internal combustion engine. The central body portion 60, the pistons 56A-D, and the arms 54 form the rigid slide body 50, whose motion, in the housing compartment 36, is essentially confined to linear movement parallel to the mutually parallel axes of rotation of the four cylindrical pistons 56A-D. Substantially no angular movement of the rigid slide body 50 relative to any of three orthogonal axes and especially with respect to the cylinders 42 will occur. Since the pistons 56A-D move along coextensive axes of the pistons 56A-D and the cylinders 42A-D, with no side force exerted by rocking piston rods as in a conventional internal combustion engine, there will be relatively little wear on the rings or the cylinder walls 44. Although the pistons 56A-D and the arms 54 can be rigidly attached or fastened to each other and to the central body portion 60, this rigid configuration lends itself to fabricating the slide body 50 as a one-piece member. In the preferred embodiments, the slide body 50 will be die cast as a one-piece member. The one configuration of the slide body 50 lends itself to being cast from a light weight material, such as aluminum or from brass or zinc or other materials so long as the material has sufficient structural strength and integrity to withstand the forces exerted upon the slide body 50 and its constituent elements. The integral slide piston subassembly 50 can also be machined. In the embodiment of
The pistons 56A-D can be rigidly attached to arms 54, but preferably the pistons 56A-D are cast as a part of the one piece slide body 50. When pistons 56A-D are cast in this manner, the pistons 56A-D can be cast as shorter cylindrical members. The opposite ends of these integrally cast pistons 56A-D can be substantially parallel, each extending substantially perpendicular to the piston arms 54 and to the central body portion 60. Piston rings 59 will be seated within grooves formed around the pistons 56A-D. These piston grooves can be fabricated as part of the die casting operation in which the integral slide body 50 is fabricated or the piston grooves can be subsequently machined as part of a secondary operation. The linear movement of the rigid piston slide body subassembly 50, and especially of the pistons 56A-D will result in even wear between piston rings 59 and the internal cylinder walls 44. The heads 90 will close off the top of each cylinder 42A-D, and O-rings 110 captured in O-ring grooves 112 in the head 90 will seal each cylinder 42A-D.
The central body 60 is relatively flat and has a height that is less than the outside diameter of the pistons 56A-D. In this embodiment the central body 60 also has a width that is greater than that of the individual piston arms 54, because the piston arms 54 must provide clearance for the pistons 56-A-D to reach top dead center in the respective cylinders 42A-D. The central body 60 also guides the four piston slide body subassembly 50 so that only linear movement is permitted without significant angular displacement during the piston stroke. In a four piston, four stroke, two cycle version of this invention, the individual pistons 56A-D will fire at four different times. Since the axes of rotation of each piston is offset from the center of mass of the slide body 50, there will be a moment created, which could tend to cause the slide body to move angularly if not for the fact that the edges of the central body portion 60 are restrained in this manner. In other words the slide body 50 might tend to cock resulting in a bureau drawer effect. Linear bearings could however be employed to overcome any bureau drawer effect.
The central body portion 60 also includes a push-pull track located on its lower face. This push-pull track extends at an acute angle relative to the axes of the pistons 56A-D as well as to the direction of travel of the piston slide body 50. The track 62 is a formed steel member, which is more resistant to wear than the cast piston-slide body 50. Track 62 has a width sufficient to receive a slide bealing72, which extend upward from one face of the flywheel 70 and be seated in the track 62. As the slide body piston 50 reciprocates, the linear movement of the piston slide body 50 is transmitted through the engagement of the projecting pin 72 with the track 62 to impart rotary motion to the flywheel 70.
The flywheel 70 is mounted below the piston slide body 50. Flywheel 70 is generally parallel to the piston slide body 50 so that the axis of rotation of the flywheel 70 extends perpendicular to the slide central body 50 and to the direction of linear reciprocation of the pistons 56 A-D during each stroke. A drive shaft 74 extends from the opposite face of the flywheel 70 from which the pin 72 projects. In this embodiment, the flywheel 70 is located in the same internal housing compartment 36 in which the piston slide body subassembly 50 is located. The drive shaft 74 extends through an opening of the lower plate or cover 20 to provide a power takeoff on the exterior of the housing 10. The pin or bearing 72 and the pin bearing 76 are offset from the axis of rotation of the flywheel 70, which is also collinear with the axis of revolution of the drive shaft 74. The pin or bearing 72, which engages the piston slide body 50 in track 62, thus revolves around the center of mass and the axis of rotation of the flywheel 70. To insure that the flywheel 70 is balanced around its axis of rotation and that the axis of rotation extends through the center of mass, material can be removed from the flywheel 70.
The flywheel 70 is cast from a material, such as aluminum, in the same manner as the piston slide body 50 and other components of this internal combustion engine 1. The mass of the flywheel 70 can, however, be increased by adding weight around the axis of revolution of the flywheel 70. In the preferred embodiment mass has been added to the flywheel by attaching magnets 80 to the flywheel 70 evenly around the drive shaft 74. The mass of the rotating flywheel 70, including magnets 80, is greater than the mass of the piston slide body subassembly 50 in the first embodiment of this invention. Typically mass is added to conventional flywheels by adding mass to the flywheel rim. In this embodiment, the magnets 80 are located closer to the center of the flywheel 70, and the mass of these magnets is greater than the mass of magnets, or other weights, that could be added adjacent to the flywheel rim and would result in the same moment of inertia. The magnets 80, are however to be used for the generation of electric current, in a manner which will be subsequently be described in more detail, and larger magnets 80 are suitable for that purpose. Therefore it was deemed appropriate to employ larger magnets 80 closer to the flywheel axis of revolution instead of smaller magnets adjacent the periphery of the flywheel 70.
In the main representative embodiment, the flywheel 70 is located within the housing compartment 36. It should be understood however that a separate rotating disk, including a drive pin, could be mounted on the interior of the housing, and the flywheel could be mounted outside the housing 10. An intermediate shaft would join the separate rotating disk and an external flywheel in this alternative configuration. The main representative embodiment would, however, accomplish the same result with fewer parts.
The flywheel 70 functions as an energy storage device to dampen or reduce the fluctuations or variations of the velocity of the piston subassembly 50 during each stroke. Obviously the force acting on the piston subassembly 50 during combustion and during the initial stages of the expansion stroke of any one piston 56A, B, C or D is greater than during later stages of each stroke, especially as the fuel air mixture is compressed in another cylinder 42A,B,C or D. The energy stored by rotation of the flywheel 70 will tend to reduce these velocity variations and smooth reciprocal movement of the piston slide body 50. However, it should be understood that while a flywheel is advantageous, it could be replaced by a crank.
The energy storage function of flywheel 70 is similar to flywheel energy storage in other conventional internal combustion engines. It is currently believed, however, that the flywheel 70 serves an additional function in the present invention. In the absence of other forces acting on the flywheel 70, the angular momentum of the rotating flywheel 70 will tend to remain constant. The direction of the angular momentum vector would also remain unchanged. When other forces act on the flywheel 70 the inertia of this flywheel 70 should make it more difficult for these forces acting on the flywheel 70 to change the direction of the angular momentum vector. In other words the angular momentum of the flywheel 70 will tend to dampen or reduce movement or vibrations, which might arise from other forces. Since the piston subassembly 50 moves in only one direction at any one time, there will be no tendency of oppositely moving pistons to balance the reaction forces acting on the engine housing as would be the case for conventional engines. However, the flywheel 70, which is connected to the housing, will tend to dampen any reaction forces acting on the engine housing 10 as a result of movement of the piston slide 50 in the opposite direction. Flywheel 70 thus serves to dampen any adverse effects arising from the elimination of pistons moving in opposite directions. Stabilizing this internal combustion engine 1 in this manner will make it more suitable for use in mobile vehicles, such as motor vehicles, air planes, lawn, garden and agricultural vehicles as well as in other off road applications. This description of the function of the flywheel 70 is currently believed to be accurate, but it is added here in an attempt to more completely describe the function of this internal combustion engine and its various components. This description is not intended to be limiting however, and any inadequate current understanding of the physics of this manner this engine and its operation does not limit the device as otherwise disclosed herein.
The combustion chamber of this engine is bounded by the cylinders 42A-D, the respective pistons 56A-D, and the heads 90. The heads 90 close off head ends of the cylinders 42A-D. The cylinder bodies 40A and 40B are attached to the side plates 24 and 26. Each cylinder body 40 comprises a cast member in which the internal cylinder walls 44 extend from a cylinder body inwardly facing face 46. The cylinder body is evacuated around the cylinder walls 44 as seen facing toward the center of the engine housing as shown in
The valve-cam-gear mounting plates 98, are attachable to the heads 90 which serve to close off distal ends of the cylinders 42A-D, and plate 98 serves as the means to mount other components on the heads 90A and 90B. A cast aluminum head 90 is shown in more detail in
Cam gears 94 are mounted on the opposite side of the mounting plate 98. Four cam gears 94 are located on each end of the engine so that one cam gear 94 will activate one of the four valves 106, 108. Two cam gears 94 are positioned in alignment with each cylinder 42, and the teeth mesh on cam gears 94 of each pair. Cams 96 on the inside of each cam gear 94 will engage the corresponding valve 106, 108 as each cam gear rotates. Individual cam gears 94 can be separately removed for repair after removal of the valve cover 104. The relative positions of the cams 96 can be adjusted, repositioned or realigned by removing a corresponding cam gear and replacing the same cam gear in a different angular position
A valve cam shaft 100 extends between above the slide body 50 between opposite ends of the engine 1, as shown in
A cam drive gear 95 mounted on each end of a valve cam shaft 100 drives the cam gears 94 of each pair. Rotation of valve cam shaft 100 thus imparts rotation to the cam gears 94 and causes the valves 106, 108 to open in proper sequence in relation to the position of the corresponding pistons 56A-D. Valve cam shaft 100 extends between opposite ends of the engine 1 above the internal housing compartment 36 in which the slide body 50 is located.
A shroud 12, which is mounted on the top cover plate 16, encloses the top of the housing compartment 36 as well as the valve cam shaft 100. Shroud 12 is shown in
Valve covers 104 are mounted on opposite ends of the housing 10, and each valve cover surrounds the valve and cam assembly on the end of the heads 90A and 90B. The valve covers contain gear oil lubricating the cam gears 94 and the cam drive gear 95 as in a gear box. Valve covers 104 can also include fins to more efficiently radiate heat.
As shown in
The basic internal components for imparting linear motion to the piston slide body 50 by the sequential combustion of a fuel-air mixture in the cylinders 42A-D, and for conversion of this linear motion to a rotary motion for output via a drive shaft 74 have now been discussed. However, one important feature of this mechanism is the ease with which it can be assembled, dissembled and serviced. The construction of the main housing 10 contributes largely to these advantages. The housing 10 includes an upper plate or cover 16 partially surrounded by an upper shroud 12, a lower plate or cover 16, two side plates 24, 26 and the two cylinder bodies 40A and 40 B at either end of the main engine housing 10. The two side plates 24 and 26 are captured at their upper and lower edges by interfitting grooves 18 on the upper cover plate 16 and lower intermitting grooves 22 on the lower cover plate 20. Upper cover plate 16 and lower cover plate 20 thus serve to hold the side plates 24, 26 in proper lateral position to define the top and sides of an internal housing compartment 36 in which both the piston slide body central portion 60 and the flywheel 70 are confined. The upper cover plate 16 is externally secured to the lower cover plate 20 on exterior of the side plates 24, 26. The cylinder bodies 40A and 40 B are fitted between recessed side faces 30 at opposite ends of the internal compartment 36 between end sections of the side plates 24 and 26. A protruding, generally rectangular protuberance 27 on each side plate 24 or 26 fits within a correspondingly shaped depression on the side of the cylinder bodies 40A and 40B. The relatively tight fit between the rectangular protuberance 27 and the depression 41 holds the cylinder bodies 40A, 40B and the side plates 24 and 26. A silicone sealant can be used to seal this joint as well as other joints of the interfitting housing components. The pistons 56A-D are positioned within the cylinders 42A-D before the side plates 24 and 26 are attached to the cylinder bodies 40A and 40B.
The sequence of steps for disassembling the internal combustion engine 1 illustrate the simplicity of servicing this engine and conversely the simplicity of its construction. After the engine is removed from the frame in which it is mounted, the valve covers 104 are removed as the first stage of the engine disassembly. The next step in breaking down the engine 1 is to remove the upper shroud 12 by removing clamps 21 securing the upper cover plate 16 to the lower cover plate 20. The valve cam shaft 100 is not free and can be removed. The upper cover plate 16 is now free and can be lifted off of the side plates 24 and 26, which are then held in place only by the lower interfitting grooves 22. Removal of the lower plate 20 will then free both the side plates 24 and 26 from the cylinder bodies 40A and 40B. Removal of the lower cover plate 20 also permits removal of the flywheel 70, which is typically removed with the lower cover plate 20. The flywheel 70 must be removed from the bottom because a tapered cavity 28 is formed on the interior of each side plate 40A and 40B to provide sufficient clearance for a flywheel 70, whose outer diameter is larger than the width of the piston slide body central portion 60. After the side plates 24 and 26 have been removed, the only remaining components are the piston slide body 50 with the pistons 56A-D still positioned within the cylinders 42A-D. Each cylinder body 40A and 40B can be removed from the slide body 50 freeing the pistons 56A-B, and disassembly of the engine 1 is now complete.
Liquid coolant is also dispersed by an external electric water or fluid pump, which although not shown, can be connected to the coolant intake 116 and exhaust 118 located on the side plate 24. The liquid coolant or water is transported between opposite ends of the main housing 10 through conduits embedded in the side plates 24, 26, generally along the path shown in
A mechanical or an electric oil pump, not shown, can be employed to circulate oil or other fluid lubricants through the engine 1. The oil pump can be located at any number of positions. Oil will be introduced into the engine 1 through the shroud 14 at the top of the engine 1, and gravity will assist in dispersing the oil. A plurality of openings 17 are provided in the top plate 16, which is positioned beneath the shroud 12. Oil will flow through these openings onto the slide body 50 and the flywheel 70, where it will be dispersed laterally. The rotating offset shaft between the bevel gear 87B and the bearing 72 will tend to laterally disperse the oil. An alternative embodiment of this invention is shown in
A linear gear bearing assembly is shown in
The main embodiment of the internal combustion engine 1 includes a single slide body 50 having four pistons 56A-D, two side-by- side pistons being located on opposite ends of the piston slide body subassembly 50. Alternative configurations can be employed. For instance, multiple slide body pistons 50 can be stacked one on top of each other. So long as both slide body piston subassemblies 50 move in the same direction, only one flywheel need be employed. If two slide bodies move in opposite directions, two flywheels can be employed, one connected to each slide body. The force generated by each pair can be transferred to a single drive shaft by conventional means. Alternatively, the same slide body can employ additional pistons extending above or below primary pistons located in the same major plane as the central slide body portion.
The representative embodiments discussed so far are not the only configurations that could employ a slide body arrangement of the type previously discussed.
The various embodiments discussed so far all employ a rotating valve cam shaft and a drive gear 95 to rotate cam gears 94, which include cam lobes 96 as either integral or attached components on the interior surface of the cam gears 94. Valve shafts 100 can be driven either by a pin and groove method or by a gear and crank method depending on the horse power of the particular engine for which this invention is employed. For smaller horsepower engines the configuration of
For a more precision version in which the valve shaft continually turns, the valve shaft 300 would employ an elliptical groove 304, as shown in
For even higher horsepower engines, the gear 87B and the crank and slide bearing 72 as shown in
Other improvements could also be added. For example, an adjustable timing mechanism could be added to the valve drive shaft. An assembly shown in
Because of the nature of the slide body, it can be made in a number of configurations. It can have from one piston and arm to multiple pistons on both ends. Multiple pistons can be side by side or the pistons can be placed at different levels.
The embodiment of
When more than four pistons in a single slide body assembly other modifications can be employed. If at least six pistons, three located side by side on each side, are employed, a further advantage can be achieved. If the two exterior pistons are fired simultaneously on both ends of the piston subassembly, and if the middle pistons are fired at different times, then the resultant force can always act through the center of mass of the slide body. Thus there will be no tendency of the slide body to become cocked as it moves, and there will be no “bureau drawer” effect. For example, if at the start of the first stroke of a four stroke, two cycle engine in the configuration shown in
Electricity can be generated by magnets 80 mounted on the flywheel 70, which will move past electrical conductors in the form of coils 84 mounted on a coil plate secured to the exterior face of the bottom plate or lower housing cover 20. As discussed previously the magnets 80 also serve the purpose of adding weight and mass to the flywheel 70, since they are bonded to the exterior of the flywheel. The coils 84 are formed by winding a first wire around iron cores in a first direction and then by winding wire around the same iron cores in a second direction. These coils 84 are then mounted on a mounting plate 82, which is secured to the exterior face of the bottom plate 20. Cavities 130 extend partially into the external face of the bottom plate 20. These cavities receive the coils 84, which are separated from the magnets 80 by a thickness of nonferromagnetic aluminum. The magnets 80, mounted on the flywheel 70, rotate within the internal housing compartment 36 relate to the stationary coils 84 on the coil plate located on the exterior of the housing 10. An electric current is induced in the electric circuit 144 including coils 84 by relative movement of the magnetic field of the magnets 80. The electricity produced in this manner can be used to power external devices, such as the oil pump and the water pump as well as to charge an external battery. This electricity can also be tapped for other uses, which are not directly related to the functioning of this internal combustion engine 1. Although they would not add as much mass to the flywheel, coils could also be mounted on the flywheel instead of using magnets. These flywheel mounted coils, which would be energized by an external electrical supply, would induce a magnetic field, which as it moved relative to the stationary coils 84, thus converting the kinetic mechanical energy of the rotating flywheel to electrical energy. The combination of flywheel mounted magnets, or other means of generating a magnetic field, along with the coils mounted on the exterior of the housing body 10 can also be used as a motor, by generating a variable current in the coils, which will cause the magnets to move and the flywheel to rotate according to well understood physical principles. This arrangement can be used as a starter motor by causing the flywheel 70 to rotate and the piston slide body 50 to reciprocate in a cyclical manner. Alternatively an electric motor of this sort can be used to deliver mechanical power for other purposes by attaching the rotating drive shaft 74, attached to the rotating flywheel 70, to an external implement. The flywheel could also be driven in this manner to provide motive power to a vehicle in which this engine is employed. This engine can therefore comprise a hybrid internal combustion / electrical engine. The same results could also be achieved by employing an externally mounted flywheel.
The embodiments depicted herein are merely representative of some of the alternative configurations, which would be apparent to one of ordinary skill in the art, could be employed in accordance with this invention. The representative embodiments depicted herein merely demonstrate the operation of the invention claimed herein.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US04/43938 | 12/28/2004 | WO | 8/1/2006 |
Number | Date | Country | |
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60533599 | Jan 2004 | US |