Abstract:
An action reaction combustion engine comprising of one or more engines with one or more pistons having adequate mass being housed in mated cylinders and having two opposing heads also having valving plumbing fuel delivery and starting means and allowed to reciprocate on linear bearings delivering a workforce on each end of back and fourth stroke one force when the pistons compresses and stops and one force when fuel ignites or high pressure air pushes and drives the piston back producing four power events every one complete reciprocating cycle or revolution of the crank or other drive mechanism.

Description:
CROSS REFERENCED TO RELATED APPLICATION 
       [0001]    This application claims the benefit of U.S. provisional patent application No. 61/854,819 filed May 3, 2013 titled action reaction combustion engine. 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    This invention has to do with internal combustible fuel burning reciprocating engines. There are several applicable types of U.S. patent classifications for this application, such as internal combustion engines where mechanical power is needed for various uses. 
         [0003]    All internal combustion engines to date are very inefficient where a big portion of the heat energy is wasted and not effectively doing all the work that it could be doing (100% input with 20-30% output). 
         [0004]    The wasted heat energy has to be carried away by a radiator or other means of cooling, the heat and pressure in a combustion chamber is the highest when the crank and piston&#39;s position is at top dead center. That is when the engine&#39;s piston and crank can do no work, driving the heat into the head and piston. The energy has no place to go. 
         [0005]    As the crank moves down and starts to gain a mechanical advantage the pressure in that cylinder continuously drops off. 
         [0006]    We have been making engines this way for about 150 years, and for most engines there is only one power stroke every forth cycle, every two revolutions of the crank, and very little change has been made in the design since the beginning of the internal combustion engine. We have used this same engine design for a long time. 
       BRIEF SUMMARY OF THE INVENTION 
       [0007]    This invention uses the theory of action reaction. The energy and forces it takes to stop a mass in motion as well as the energy and forces it takes to accelerate it again and its ability to do work with those forces are the bases of my invention. 
         [0008]    This invention uses the engine&#39;s reciprocating motion and the energy and forces that this motion produces by starting and stopping the mass of the pistons to turn a crank flywheel drive shaft pump or other type of drive mechanisms. 
         [0009]    This technology is not new, but has never been used in the application for a combustion engine. 
         [0010]    When the energy and forces that are applied to a crank are as close as possible to 90 degrees after top dead center is when the mechanical advantages are at their optimum. That is exactly what this engine will accomplish. 
         [0011]    Not only does it gain a 90 degree mechanical advantage, but it also delivers four power events every reciprocating cycle or revolution of crank, two events when the mass stops on each opposite end and two when the mass reverses direction and starts the mass moving again on each opposite end. 
         [0012]    The engine pushes and pulls the crank in both directions, but does so with a very simple design and few moving parts. It will burn most any kind of fuel and will be very efficient. 
     
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         [0013]      FIG. 1  depicts most of the descriptive parts of the main embodiment. 
           [0014]      FIG. 2  depicts the valving and valving control for adjusting exhausting air and air inlet valving for controlling air intake for starting and or running on air. 
           [0015]      FIG. 3  depicts the engine as a one-piston engine having separable cylinder. 
           [0016]      FIG. 4  depicts the engine attached to a crank. 
           [0017]      FIG. 5  depicts the engine supported by bearings and being fastened together with fasteners. 
       
    
    
     DESCRIPTION 
       [0018]    An action reaction free piston combustion engine composed of one or more said engines connected to a crank or other drive mechanism consisting of one or more pistons and cylinders. 
         [0019]    Said engines with three or more said pistons traveling together and being attached by rods and are allowed to reciprocate. 
         [0020]    The two smaller said pistons on each end and the one large heavy said piston in the center are moveable and mated to their perspective said cylinders separated by two bulkheads. The said rods and said pistons are supported by lineal bearings. 
         [0021]    The said lineal bearings being mounted in said bulkheads and said pistons having adequate mass to produce action reaction necessary to push and pull said engine and said engine is allowed to reciprocate on said lineal bearings against a workload like a crank to transmit energy, and that energy into work. 
       DETAILED DESCRIPTION OF THE INVENTION 
       [0022]    I have numbered every part at least once with out numbering them twice where opposing parts are identical and obvious, the engine will always be referred to as the number 1. To begin in  FIG. 1  the major parts for said engine  1  being an example of a three cylinder engine include one cylinder  2  in the center and two cylinders  3  on opposing ends of said engine  1  along with opposing cylinder heads  15  being fastened together with fastener means  20  in  FIG. 5 . 
         [0023]    The three said cylinders of said engine  1  in  FIG. 1  being fitted with three pistons, one large center said piston  4  and two smaller end said pistons  5  and are movable in and mated to their perspective said cylinders  2  and  3  and are allowed to reciprocate freely in said cylinders  2  and  3 , compressing and firing on one end while the other end is exhausting. 
         [0024]    The said pistons  4  and  5  are attached together by rods  6  if applicable running through bulkheads  14  for separating said pistons  4  and  5  and said cylinders  2  and  3 . 
         [0025]    Said pistons  4  and  5  are supported by lineal bearing means  10  that are mounted in said bulkheads  14 . 
         [0026]    Said pistons  4  and  5  are allowed to reciprocate in their perspective said cylinders  2  and  3 . Said pistons  5  are allowed to compress against the said cylinder heads  15  in turn pushing and pulling said engine  1  backward and forward while riding on said bearing means  21  as depicted in  FIG. 5  and producing a work force. 
         [0027]    The valving control rods  7  and valve adjusters  16  in  FIG. 1  are for timing the exhaust valves  9 , letting the exhaust out through said valves  9  mounted in said cylinder heads  15 . 
         [0028]    Plumbing means in  FIG. 1  consisting of tubes  8  connected between said cylinders  2  and  3  with check valves  13 , located in said tubes  8  and taking out side air in through one way valves  12  where air is drawn in to said cylinder  2  and then compressed and sent through said tube  8  and past said check valve  13  into said cylinder  3  that is in position to exhaust and that said cylinder  3  is then purged out through said valve  9  for that end of said engine  1 . 
         [0029]    As one end of said engine  1  in  FIG. 1  is exhausting out through said valve  9  in said cylinder head  15 , the other end of said engine  1  is firing by means of a timed fuel injector  11  located in the end of said cylinder head  15 , and the cycle repeats firing on one end and exhausting on the other. 
         [0030]      FIG. 2  drawing is a example of said engine  1  as the starter and an air engine where the air inlet valves  17  are properly timed to let high pressure air into said cylinder  2  and the air pressurizing said cylinder  2 , and applying high pressure air between said piston  4  and said bulkhead  14 , pushing said bulkhead  14  and said piston  4  apart, and pushing said bulkhead forward and said piston  4  backward causing said engine  1  to reciprocate producing a action reaction. 
         [0031]    While said piston  4  is pressurizing and pushing one end of said engine  1  in  FIG. 2 , exhausting is taking place simultaneously on opposite end of said cylinder  2  of said engine  1  and exhausts out through valve  9 A, and said valve  9 A, being timed by said valving control rod  7  and valve adjuster  16   a.  So said piston  4  and said engine  1  now becomes a starter as well as air engine starting the said combustion engine  1  as well as to assist in the over all output of the said combustion engine  1 . 
         [0032]      FIG. 3  is a drawing of said engine  1  having only one piston  4   a,  and being of one piece with a larger center portion and having adequate mass and being movable and housed in cylinder  2   a  and said cylinder  2   a  being separable. 
         [0033]    Each end of the said piston  4   a,    FIG. 3  which is the two outboard ends of said piston  4   a  and being housed in said cylinders  3   a  which is the outboard end of said cylinder  2   a  and said piston  4   a  being slidable in lineal bearing means  10   a  and said piston  4   a  being allowed to reciprocate. 
         [0034]    Said engine  1  in  FIG. 3  having same parts including said valves  9  and said valve adjusters  16 , said cylinder heads  15 , and said plumbing means consisting of said tubes  8  with said check valves  13  and said fuel delivery injectors  11  as in said engine  1  in  FIG. 1  except said lineal bearing means  10   a,  being in drawing for said engine  1   FIG. 3  and as well as the same said engine starting means as in said engine  1   FIG. 2 , and having same said bearing means  21  as in  FIG. 5 . 
         [0035]    And said engine  1  of  FIG. 3  being attached to same said crank  19  or other said drive mechanism as in said engine  1   FIG. 4 . 
         [0036]      FIG. 4  is a drawing of said engine  1  in  FIG. 1 ,  FIG. 2 , and  FIG. 3  being connected to said crank  19  in  FIG. 4  and said engine  1  is allowed to reciprocate on said bearing means  21  in  FIG. 5  and turning said crank  19  in  FIG. 4 , producing a force against a workload. 
         [0037]    The drawing in  FIG. 5  shows said engine  1  mounted on said bearing means  21  and allowed to reciprocate and is fastened together with said fastener means  20 .