Not Applicable
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1. Field of the Invention
This invention relates to improvements in an internal combustion engine. More particularly each cylinder is divided into two chambers by the piston where the upper chamber is used for combustion and the lower chamber is used for air pumping and initial compression.
When the internal combustion engine is used as a two-stroke engine the engine size can be reduced by up to 50% of an existing four-stroke engine.
When the internal combustion engine is used as a four-stroke engine the engine will be similarly sized to an existing four-stroke engine except the chamber under the piston will work as a supercharger and improve efficiency.
2. Description of Related Art Including Information Disclosed Under 37 CFR 1.97 and 1.98
Numerous patents have been issued on piston driven engines. The majority of these engines use pistons that move up and down in a cylinder. The piston is connected to a crank shaft and the piston pivots on a wrist pin connected to the piston connecting rod. The side-to-side motion of the piston rod eliminates the potential for a sealing surface under the piston. The design of an engine with piston rods that remain in a fixed orientation to the piston allow for a seal to exist under the piston and this area can be used as a pump to increase the volume of air being pushed into the top of the piston to turbo-charge the amount of air within the cylinder without use of a conventional turbo charger driven from the exhaust or the output shaft of the engine. Several products and patents have been issued that use piston rods that exist in fixed orientation to the piston. Exemplary examples of patents covering these products are disclosed herein.
There is a large amount of energy that is lost due to aerodynamic drag from the piston pushing air under a piston as it moves. In existing engines that use only the top of the piston energy is wasted from the aerodynamic drag. In a dual chamber cylinder there is no aerodynamic drag.
U.S. Pat. No. 3,584,610 issued Jun. 15, 1971 to Kilburn I. Porter discloses a radial internal combustion engine with pairs of diametrically opposed cylinders. While the piston arms exist in a fixed orientation to the pistons the volume under the pistons is not used to pump air into the intake stroke of the engine.
U.S. Pat. No. 4,459,945 issued Jul. 17, 1984 to Glen F. Chatfield discloses a cam controlled reciprocating piston device. One or opposing two or four pistons operates from special cams or yokes that replace the crankpins and connecting rods. While this patent discloses piston arms that are fixed to the pistons there also is no disclosure for using the area under each piston to move air into the intake stroke of the piston.
U.S. Pat. No. 4,480,599 issued Nov. 6, 1984 to Egidio Allais discloses a free-piston engine with operatively independent cam. The pistons work on opposite sides of the cam to balance the motion of the pistons. Followers on the cam move the pistons in the cylinders. The reciprocating motion of the pistons and connecting rod moves a ferric mass through a coil to generate electricity as opposed to rotary motion. The movement of air under the pistons also is not used to push air into the cylinders in the intake stroke.
U.S. Pat. No. 6,976,467 issued Dec. 20, 2005 and published application US2001/0017122 published Aug. 30, 2001, both to Luciano Fantuzzi disclose an internal combustion engine with reciprocating action. The pistons are fixed to the piston rods, and the piston rods move on a guiding cam that is connected to the output shaft. These inventions use the piston was as a guide for reciprocating action and thereby produce pressure on the cylinder walls. The dual chamber design uses piston wall and a guided tube in the bottom of the lower chamber as guides for the piston in the reciprocating action. Neither of these two documents discloses using the lower chamber as a supercharger.
What is needed is an engine where the underside of the piston is used to compress the air and work as a supercharger for the upper chamber cylinder. This application discloses and provides that solution.
It is an object of the engine with dual chamber cylinders to utilize the underside of a piston to act as a supercharger or compressor for the engine use or other uses.
It is an object of the engine with dual chamber cylinders to use a guided tube in the bottom of the cylinder and an ellipse shaft to convert reciprocating rectilinear motion into rotational motion.
It is an object of the engine with dual chamber cylinders to use the upper chamber as a four-stroke engine and the lower chambers as a compressor or supercharger.
It is an object of the engine with dual chamber cylinders to use a split cycle or two-stroke engine by using the upper chamber as combustion/exhaust and the lower portion of the cylinder as an air/compressor. This design can result in a reduction of the engine size by up to 50%.
It is an object of the engine with dual chamber cylinders to eliminate friction that is created by the piston rocking and being pushed and pulled side-to-side with the piston arm. The side-to-side force is eliminated because the piston is pushed and pulled linearly within the cylinder thereby eliminating the side-to-side rotation and friction.
It is an object of the engine with dual chamber cylinders to eliminate the aerodynamic forces and drag from under the piston.
It is an object of the engine with dual chamber cylinders that the area under the chamber works as a shock absorber for the area above the piston thereby making the engine operate quieter.
It is an object of the engine with dual chamber cylinders to be used for an airplane engine because the engine can be lighter in weight and higher in efficiency.
It is an object of the engine with dual chamber cylinders to eliminate the crankshaft, camshaft, cam sprocket, timing belt, timing belt tensioner and outside supercharger or turbocharger. The elimination of the identified components can reduce the space, weight and cost and energy consumption.
It is an object of the engine with dual chamber cylinders to save energy of the dual chamber verses existing four-stroke engine because the engine is lighter, lower friction, no side forces in the piston, fewer parts and no aerodynamic drag from under the piston as it moves within the cylinder.
It is still another object of the engine/compressor with dual chamber cylinders to use the engine/compressor as a compressor, pump for other function by using the motor to turn the elliptical shaft.
Various objects, features, aspects, and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the invention, along with the accompanying drawings in which like numerals represent like components.
The engine/compressor can be one of four types. Type I is a two-stroke engine, Type II is a four-stroke engine with supercharger, Type III is a four-stroke engine without supercharger and Type IV is a compressor cylinder. The figures show various spaces above and below the pistons. These spaces are for the purposes of illustration only and change based upon the design requirements. In general the spacing above a piston is greater than the spacing below the piston for clearance of a spark plug, air movement and or fuel injection.
The piston rod 41 will slide in and out of the cylinder through a guided tube in one end of the cylinder using a low friction seal 42. The piston, which can slide with reciprocating rectilinear motion inside the cylinder between a bottom dead center (BDC) and top dead center (TDC) a device such as an ellipse shaft converts the reciprocating rectilinear motion of the piston into rotary motion of the engine shaft. The piston arm 41 movement distance between the bottom dead center (BDC) and the top dead center (TDC) is equal to a half difference of the major axis and the minor axis of the ellipse shaft and each shafting will turn the engine shaft at 90 degrees rather than 180 degrees as in an existing engine. The ellipse or elliptical crank 100 shaft has two walls, an inside wall 101 to push the piston rod into the cylinder and an outside wall 102 to pull out the piston rod out of the cylinder. The ellipse or elliptical crank is shown and described in more detail with
A head 31 closes the top of the cylinder 30. The head 31 includes provisions for a fuel injector 70 for supplying fuel into the air stream of the intake and a spark plug 71 to ignite a compressed gas/air mixture with the cylinder 30. Air enters into the cylinder from the intake port where air 81 comes in 80 through an intake check valve. Exhaust air 91 exits the cylinder from the exhaust port where exhaust air 91 comes through the exhaust valve 90. The exhaust valve 90 is held closed by an exhaust valve spring 92 that pushes on an opposing exhaust valve spring stop 93. The exhaust valve 90 has an exhaust valve lifter 94 that is lifted with an exhaust cam lobe 95 located on the crank 100.
The piston 40 seals against the inside of the cylinder 30 with a series of compression 50 and oil rings 51. An oil tube or pipe 60 and an oil drain 61 moved oil out the piston. The oil passage into the oil pipe 60 is shown and described in more detail with
The piston rod 41 will slide in and out of the cylinder through a guided tube in one end of the cylinder using a low friction seal 42. The piston, which can slide with reciprocating rectilinear motion inside the cylinder between a bottom dead center (BDC) and top dead center (TDC) a device such as an ellipse shaft converts the reciprocating rectilinear motion of the piston into rotary motion of the engine shaft. The piston arm 41 movement distance between the bottom dead center (BDC) and the top dead center (TDC) is equal to a half difference of the major axis and the minor axis of the ellipse shaft and each shafting will turn the engine shaft at 90 degrees rather than 180 degrees as in an existing engine. The ellipse or elliptical crank 100 shaft has two walls, an inside wall 101 to push the piston rod into the cylinder and an outside wall 102 to pull out the piston rod out of the cylinder. The ellipse or elliptical crank is shown and described in more detail with
A head 31 closes the top of the cylinder 30. The head 31 includes provisions for a fuel injector 70 for supplying fuel into the air stream of the intake and a spark plug 71 to ignite a compressed gas/air mixture with the cylinder 30. Air enters into the cylinder from the intake port where air 81 comes in 80 through an intake valve 80. The air that enters from the intake valve 80. The intake valve is held closed by an intake valve spring 82 that pushes on an opposing intake valve spring stop 83. The intake valve 80 has an intake valve lifter 84 that is lifted with an intake cam lobe 85 located before the crank 100. Exhaust air 91 exits the cylinder from the exhaust port where exhaust air 91 comes through the exhaust valve 90. The exhaust valve 90 is held closed by an exhaust valve spring 92 that pushes on an opposing exhaust valve spring stop 93. The exhaust valve 90 has an exhaust valve lifter 94 that is lifted with an exhaust cam lobe 95 located after the crank 100.
The piston rod 41 will slide in and out of the cylinder through a guided tube in one end of the cylinder using a low friction seal 42. The piston, which can slide with reciprocating rectilinear motion inside the cylinder between a bottom dead center (BDC) and top dead center (TDC) a device such as an ellipse shaft converts the reciprocating rectilinear motion of the piston into rotary motion of tan engine shaft. The piston arm 41 movement distance between the bottom dead center (BDC) and the top dead center (TDC) is equal to a half difference of the major axis and the minor axis of the ellipse shaft and each shafting will turn the engine shaft at 90 degrees rather than 180 degrees as in an existing engine. The ellipse or elliptical crank 100 shaft has two walls, an inside 101 wall to push the piston rod into the cylinder and an outside wall 102 to pull out the piston rod out of the cylinder. The ellipse or elliptical crank is shown and described in more detail with
Two-Stroke Engine/Split Cycle Engine
A fuel injector 70 and a spark plug 71 exist on the top or head of the cylinder. On the up stroke of a piston 40 atmospheric air 120 is brought into the underside of the cylinder 30 through a one-way check valve 122. When the piston 40 goes down the air within the cylinder is compressed and passes through a piston actuated valve 110 and through a one way check valve 123 where the pressurized air line 121 pushes the compressed air into the top of a piston though one-way check valve 86 where it is mixed with injected fuel from the fuel injector 70 and detonated with the spark plug 71. The piston 40 is then driven down with the expanding gas. The piston 40 then moves up and expel the burnt exhaust through valve 96 and out the exhaust port 91.
The engine in
Four-Stroke Engine
In
From the detail shown in
A third alternative is to lubrication using a fuel and oil mixture that is commonly used with two stroke engines.
Thus, specific embodiments of a dual chamber cylinder engine have been disclosed. It should be apparent, however, to those skilled in the art that many more modifications besides those described are possible without departing from the inventive concepts herein. The inventive subject matter, therefore, is not to be restricted except in the spirit of the appended claims.
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20040261732 | Fantuzzi | Dec 2004 | A1 |
20050095770 | Major | Oct 2005 | A1 |
20080121196 | Fantuzzi | May 2008 | A1 |
20080141855 | Fisher | Jun 2008 | A1 |
Number | Date | Country |
---|---|---|
W09849434 | Nov 1998 | WO |
Number | Date | Country | |
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20100071640 A1 | Mar 2010 | US |