NATURE AND PURPOSE OF THE INVENTION
An engine having 2-sided pistons in a single cylinder and moving in a linear motion to reduce the lateral friction of the pistons with a view to providing the pistons to have less wear and tear and to move in a balanced motion by using less parts than an engine at present.
FIELD OF THE INVENTION
Engine engineering and engineering relating to engines.
BACKGROUND OF THE INVENTION
Four-stroke internal combustion engines which are in use today are subjected to development and improvement continually but their original power transmission form namely the pistons transmitting power to a connecting rod and towards a crankshaft cannot be developed. The movement of the pistons in an engine normally generates friction on a lateral side of the pistons which is the rolling radius side of a crank. The friction causes the pistons and the cylinder to undergo wear and tear and lose energy. Moreover, crankshafts which are in use today have light weight and the friction thus causes energy loss in a useless manner. When a close patent is taken into account such as U.S. Pat. No. 4,106,443 which relates to cylinder heads, there is great development nowadays. However, there are limitations in respect of the size and the number of valves which cause obstacles in the flow of an air-fuel mixture and exhaust gases. Previous development of cylinder heads has dealt with the development of spherical rotary valve assemblies as shown in U.S. Pat. Nos. 4,944,261; 4,989,558.
BRIEF SUMMARY OF THE INVENTION
The invention provides a new configuration of the cylinder head in which the conventional valve arrangement is replaced by a rotor which has openings communicating with intake and exhaust ports of the cylinder to control air-fuel intake into the cylinder and exhaust gases from the cylinder.
This results in a reduced number of parts and provides smooth flow of the air-fuel mixture and exhaust gases without obstruction by the valve face to such flow.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 A two-way cylinder and a balanced-arm type connecting rod.
FIG. 2 A two-way cylinder and an oblique-arm type connecting rod in a model of an engine using a double parallel guide rail platform.
FIG. 3 A two-way cylinder and two-way pistons using a single arm type connecting rod.
FIG. 4 A two-way and a single arm type connecting rod in a model of an engine using a single guide rail platform.
FIG. 5 A form of an engine with a one-shaft type two-way piston.
FIG. 6 A form of an engine with a 2-shaft type two-way piston.
FIG. 7 A form of an engine with a 4-shaft type two-way piston.
FIG. 8 The end of a connecting rod arm fitted with a ball sleeve.
FIG. 9 A guide rail platform used with a 2-cylinder engine, and a 4-cylinder engine.
FIG. 10 A guide rail platform used with a parallel rail type 4-cylinder engine.
FIG. 11 A guide rail platform used with a single rail type 4-cylinder engine.
FIG. 12 A form of a 4-cylinder engine with two-way pistons using a guide rail platform.
FIG. 13 A form of the positioning of the piston of a 2-cylinder type two-way piston engine.
FIG. 14 A figure showing the detail of the cylinder head of an engine.
FIG. 15 A figure showing the detail of a 4-cylinder type two-way piston engine using a single guide rail platform and a single connecting rod arm.
FIG. 16 A figure showing the detail of a 4-cylinder type two-way piston engine using a single guide rail platform and a balanced connecting rod arm.
FIG. 17 A layout showing the position of the piston and the position of the ignition of a 2-cylinder type two-way piston engine.
FIG. 18 A layout showing the position of the piston and the position of the ignition of a 4-cylinder type two-way piston engine using a single guide rail platform.
FIG. 19 A layout showing the position of the piston and the position of the ignition of a 4-cylinder type two-way piston engine using a double parallel guide rail platform.
DETAILED DISCLOSURE OF THE INVENTION
An object of the present invention is to allow the pistons to move in a linear motion only. The engine has separate pistons (FIG. 1) in upper and lower opposed positions or a two-way piston (FIG. 3) having chambers at the head and the tail of the two-way piston. The pistons in FIG. 1 are connected by a connecting rod to move together in a dual cylinder (1). The connecting rod has an extending arm 2 (hereinafter referred to as the connecting rod arm). The connecting rod arm (2) will transfer the power of the two pistons at a power stroke to the drive shaft with various forms of power transmission as follows:
- A.1 It is designed to provide the transmission of power to one crankshaft only.
- A.2 It is designed to provide the transmission of power to two crankshafts.
- A.3 It is designed to provide the transmission of power to four crankshafts.
- A.4 It is designed to provide the transmission of power to a drive shaft by a guide rail platform.
- A.1 A design providing the transmission of power to one crankshaft by making a connecting rod arm (3) to be an axis for another connecting rod (4) to fit together and the connecting rod (4) joins a crank (5) by having a crankshaft (6) rotating horizontally opposing the line of the two-way cylinder which is in a horizontal direction (FIG. 5.1). The force derived from 2 pistons will be transmitted to the connecting rod arm at both sides in an equal amount thus causing the pistons to move in a balanced motion while the cranks at both sides which are connected to the double connecting rod arm can be designed to be light weight. The crankshaft which is fitted transversely will be eccentrically at the motion line of a connecting rod arm (7) and thus causing the crankshaft movement to sustain reduced friction.
- A.2 A design providing the transmission of power to 2 crankshafts by making a connecting rod arm (3) to be an axis for another connecting rod (4) to fit together and the connecting rods (4) join a crank (5) by having crankshafts (6) rotating perpendicularly to the two-way cylinder while the crankshafts are separated in such a way that each crankshaft is at each side of the two-way cylinder along the connecting rod arm (6) and have synchronous rotations at both shafts.
- A.3 A design providing the transmission of power to 4 crankshafts by making a connecting rod arm (3) to be an axis for another two connecting rods (4) to fit together and the connecting rod (4) joins a crank (5) by having crankshafts (6) rotating perpendicularly to the two-way cylinder while the crankshafts are separated in such a way that two crankshafts are at each side along the connecting rod arm (FIG. 7) and thus causing the 4 crankshafts to have synchronous rotations in a balanced motion at all sides.
- A.4 A design providing the transmission of power to a drive shaft by a guide rail platform by making the end of the arm 2 of the connecting rod 1 to be a ball sleeve (FIG. 8). A transmission shaft (8) is tightly fitted with a guide rail platform (9). The transmission shaft is fitted parallel to the two-way cylinder whereas the connecting rod arm at the side where it is constructed as a ball sleeve is in the rail (10) of the guide rail platform (9) while the connecting rod arm at another side is fitted to a small connecting rod (FIG. 16) in a small two-way cylinder fitted laterally to the two-way cylinder which functions as an engine oil pump. It does not matter whether the connecting rod arm which is attached to the small connecting rod in the small two-way cylinder is present or not. The design to provide transmission to the drive shaft directly comprises one two-way cylinder or more. For the purpose of balance, at least 2 two-way cylinders should be fitted in the same plane and their clearance from both sides of the transmission shaft should be equal and this number can be increased to 4 cylinders with the transmission shaft being at the center surrounded by 4 two-way cylinders. Each cylinder has an equal clearance from the transmission shaft and forms an angle of 90 degrees, 180 degrees, 270 degrees and 360 degrees (FIG. 12). The end of the connecting rod arm of each two-way cylinder is in the rail of the guide rail platform with the pistons being placed alternately in each two-way cylinder.
The Operation of a Linear Motion Piston is as Follows:
Referring to FIG. 13, the piston 1 is at the highest position, moving down to perform the intake stroke of the piston 1. When moving towards the lowest position, it ascends to perform the compression stroke and performs the power stroke when ascending to the highest position to generate power and descends to the lowest position and then ascends to perform the exhaust stroke. At the highest position, a new cycle begins. The movement to the highest and lowest positions also produces an effect on piston 2 on the opposite direction.
The ignition of piston 1 and piston 2 should be determined in successive positions. That is to say, after the piston 1 is at the highest ignition position when it descends, it means piston 2 begins to ascend. When the piston 1 is at the lowest position, the piston 2 is at the highest ignition position.
With the above principle, designs A.1, A.2, A.3 can work even with 1 two-way cylinder. If continuous operations and balance are required, there should be 2 or more two-way cylinders.
Regarding design A.4, there should be at least 2 two-way cylinders for balanced operations and 4 two-way cylinders for balanced and continuous operations.
The Operation of the New Piston is as Follows:
The cylinder head is constructed as 2 layers with a spherical rotor blade (FIG. 14.5) rotating between the upper cylinder head (FIG. 14.2) and the lower cylinder head (FIG. 14.3). The lower cylinder head (FIG. 14.1) is perforated with 2 ports whereby the two ports are on the hemisphere of the cylinder head sphere (FIG. 14.1). An intake port (12) and an exhaust port (11) of the upper cylinder head in contact with the rotor blade (FIG. 14.2) are provided with a seal (13) to prevent leakage pressure around both ports. The middle of the top of the lower cylinder head (FIG. 14.2) is constructed with an edge in high relief (14) with a port for a spark plug (15) while the high-relief edge is the core for a rotor blade. The rotor blade is of a circular nature with its outermost edge having gear teeth (18) to which a seal (19) is fitted to prevent leakage pressure at both sides of the rotor blade. The middle of the rotor blade is perforated with a hole having a size equal to the width of the high-relief edge of the lower cylinder head. The inner edge of the rotor blade is fitted with ball bearings (20) to reduce friction and a seal (21) prevent leakage pressure is fitted to the edge of ball bearings at both sides of the rotor blade. There is one port (22) perforated between the inner and outer sides of the leakage pressure prevention seal (FIG. 14.5). The lower cylinder head (FIG. 14.3) in contact with the rotor blade is perforated with an intake port and an exhaust port (FIG. 14.3) which is similar to the lower cylinder head and in the corresponding position. The edges of the intake port and exhuast port are fitted with a seal (13) to prevent leakage pressure. The upper part of the upper cylinder head is perforated to receive an intake port (17) and an exhaust port (16). The middle of the upper cylinder head is perforated with a hole having a size equal to the width of the high-relief edge of the lower cylinder head (FIG. 14.4).
When the lower cylinder head and the upper cylinder head have been assembled already, there is a space exactly fit the width of the rotor blade. The rotation between the rotor blade and gears (23) in designs A.1, A.2, A.3 has a gear ratio of 1:2. For design A.4, the gearing ratios are different between the fitting of 2 two-way cylinders which has a gear ratio similar to design A.1, A.2, A.3 and the fitting of 4 two-way cylinders which has a gear ratio of 1:1. The opening and closing of the flow of an air-fuel mixture and exhaust gases use a reduced number of parts and facilitate a better flow of an air-fuel mixture and exhaust gases. In operation, the parts of the rotor blade requires no special lubrication.
Operation of an Overall Engine
The design A.1 engine operate with only one two-way cylinder. If continuous power is required, 2 or more two-way cylinders should be used by fitting parallel and placing the pistons of each cylinder as per FIG. 13.1, FIG. 13.2.
FIG. 17.1, 17.3 Cycle A Pistons (1), (4) ascend to the highest positions
- Pistons (2), (3) descend to the lower positions
FIG. 17.2, 17.4 Cycle B Pistons (2), (3) ascend to the highest positions
- Pistons (1), (4) descend to the lower positions
FIG. 17.5, 17.7 Cycle A Pistons (1), (3) ascend to the highest positions
- Pistons (2), (4) descend to the lower positions
FIG. 17.6, 17.8 Cycle A Pistons (2), (4) ascend to the highest positions
- Pistons (1), (3) descend to the lower positions
FIG. 17.1 Piston (1) is at the ignition position.
FIG. 17.2 Piston (2) is at the ignition position.
FIG. 17.3 Piston (4) is at the ignition position.
FIG. 17.4 Piston (3) is at the ignition position.
FIG. 17.5 Piston (1) is at the ignition position.
FIG. 17.6 Piston (2) is at the ignition position.
FIG. 17.7 Piston (3) is at the ignition position.
FIG. 17.8 Piston (4) is at the ignition position.
The operation of the design A.1 engine which is a two-way cylinder type is one ignition per each cycle when the piston ascends to the highest position and descends to the lowest position and thus producing continuous torque down to the crankshaft. In fitting the crankshaft in the design A.1 engine, the center of the crankshaft with the motion line of the connecting rod arm should not exceed 45 degrees from the line of the two-way cylinder.
The design A.2 engine operates in the same manner as the design A.1 engine in all respects except the transmission of power to the crankshafts where there are 2 crankshafts perpendicular to the line of the two-way cylinder while the left crankshaft and the right crankshaft rotate synchronously.
The design A.3 engine operates in the same manner as the design A.2 engine in all respects including the transmission of power to the crankshafts. However, there is an additional crankshaft present at each side whereby the 4 crankshafts rotate simultaneously and synchronously.
The design A.4 engine which has 2 two-way cylinders operates in the same manner as the engines of designs A.1, A.2, A.3 in all respects.
The design A.4 engine which has 4 two-way single rail type cylinder operates as follows: (FIG. 18).
FIG. 18 Cycle A Pistons (1), (2) ascend to the highest point. Pistons (5), (6) descend to the lowest point.
- Pistons (7), (8) ascend to the highest point. Pistons (3), (4) descend to the lowest point.
Cycle B Pistons (5), (6) ascend to the highest point. Pistons (1), (2) descend to the lowest point.
- Pistons (3), (4) ascend to the highest point. Pistons (7), (8) descend to the lowest point.
FIG. 18.1 This causes piston (1) and piston (7) to be at the ignition position in cycle A.
FIG. 18.2 This causes piston (5) and piston (3) to be at the ignition position in cycle B.
FIG. 18.3 This causes piston (2) and piston (8) to be at the ignition position in cycle A.
FIG. 18.1 This causes piston (6) and piston (4) to be at the ignition position in cycle B.
The operation of the design A.4 engine which has 4 two-way single rail type cylinders is that in cycle A, each time there is ignition at two pistons in the opposite direction and in cycle B, each time there is ignition at two pistons in the opposite direction. This results in one rotation of the transmission shaft with 8 times of ignition from 4 two-way cylinders. The power obtained from the engine has continual high torque with reduced vibration.
The design A.4 engine which has 4 two-way double parallel rail type cylinders operates as follows:
FIG. 19 Cycle A Pistons (4), (7) ascend to the highest point. Pistons (8), (3) descend to the lowest point.
- Pistons (1), (2), (5), (6) are at the middle
Cycle B Pistons (1), (6) ascend to the highest point. Pistons (5), (2) descend to the lowest point.
- Pistons (3), (4), (7), (8) are at the middle
Cycle C Pistons (3), (8) ascend to the highest point. Pistons (7), (4) descend to the lowest point.
- Pistons (1), (2), (5), (6) are at the middle
Cycle D Pistons (2), (5) ascend to the highest point. Pistons (6), (1) descend to the lowest point.
- Pistons (3), (4), (7), (8) are at the middle
FIG. 19.1 The piston (4) is set to be at the ignition position in cycle A.
FIG. 19.2 The piston (6) is set to be at the ignition position in cycle B.
FIG. 19.3 The piston (8) is set to be at the ignition position in cycle C.
FIG. 19.4 The piston (2) is set to be at the ignition position in cycle D.
FIG. 19.5 The piston (7) is set to be at the ignition position in cycle A.
FIG. 19.6 The piston (1) is set to be at the ignition position in cycle B.
FIG. 19.7 The piston (3) is set to be at the ignition position in cycle C.
FIG. 19.8 The piston (5) is set to be at the ignition position in cycle D.
The operation of the design A.4 engine which is of 4 parallel rail type cylinders is that in every cycle A, cycle B, cycle C, cycle D, each time there is one piston provides ignition and in one rotation of the shaft, there are 4 times of ignition and the piston will complete its operation cycle when the shaft rotates two turns in the same manner as a general 4-stroke engine. The torque derived from the parallel-rail type engine of design A.4 provides continuous power at every 90 degrees of the rotation of the transmission shaft.
The transmission of power to the shaft in the design A.4 engine which has 2 cylinders is through a connecting rod arm to a guide rail platform which is fixedly attached to the transmission shaft. The rails in the guide rail platform of the design A.4 engine which has 2 cylinders are of a rail type, one is fitted at the highest position and one is fitted at the lowest position in the opposite direction on the platform. The rails are inclined from the highest position to the lowest position and from the lowest position to the highest position in one cycle of the guide rail platform (FIG. 9).
Referring to the guide rail platform of the design A.4 engine which has 4 cylinders, the rails in the guide rail platform can have various embodiments. For example:
- A single rail having two points for the highest positions and two points for the lowest positions on the same guide rail platform. The highest positions are opposite to each other and the lowest positions are opposite to each other.
- The highest position forms an angle of 90 degrees and 270 degrees with the center of the guide rail platform.
- The lowest position forms an angle of 180 degrees and 360 degrees with the center of the guide rail platform.
- Parallel rails having a form similar to the design A.4 engine which has 2 cylinders. The rails are parallel along the same platform and the position for placing two-way cylinders is similar to the design A.4 engine which has 4 single-rail type cylinders (FIG. 10)
The disclosed two-way engine can operate as a two-stroke engine with suitable ports and this two-way engine can perfectly operate as a four-stroke diesel engine.
Any other modifications can be performed to the engine by any person skilled in the pertinent art or science without departing from the scope and objects of the present invention as stated in the claims.
BEST MODE OF THE INVENTION
As described in the heading of the full disclosure of an engine invention.