The present invention is directed to a steam engine and, more particularly, to a heat regenerative engine which uses water as the working fluid, as well as the lubricant, and wherein the engine is highly efficient, environmentally friendly and adapted for multi-fuel use.
Environmental concerns have prompted costly, complex technological proposals in engine design. For instance, fuel cell technology provides the benefit of running on clean burning hydrogen. However, the expense and size of fuel cell engines, as well as the cost of creating, storing, and delivering fuel grade hydrogen disproportionately offsets the environmental benefits. As a further example, clean running electric vehicles are limited to very short ranges, and must be regularly recharged by electricity generated from coal, diesel or nuclear fueled power plants. And, while gas turbines are clean, they operate at constant speed. In small sizes, gas turbines are costly to build, run and overhaul. Diesel and gas internal combustion engines are efficient, lightweight and relatively inexpensive to manufacture, but they produce a significant level of pollutants that are hazardous to the environment and the health of the general population and are fuel specific.
The original Rankin Cycle Steam Engine was invented by James Watt over 150 years ago. Present day Rankin Cycle Steam Engines use tubes to carry super heated steam to the engine and, thereafter, to a condenser. The single tubes used to pipe super heated steam to the engine have a significant exposed surface area, which limits pressure and temperature levels. The less desirable lower pressures and temperatures, at which water can easily change state between liquid and gas, requires a complicated control system. While Steam Engines are generally bulky and inefficient, they tend to be environmentally clean. Steam Engines have varied efficiency levels ranging from 5% on older model steam trains to as much as 45% in modern power plants. In contrast, two-stroke internal combustion engines operate at approximately 17% efficiency, while four-stroke internal combustion engines provide efficiency up to approximately 25%. Diesel combustion engines, on the other hand, provide as much as 35% engine efficiency.
With the foregoing in mind, it is a primary object of the present invention to provide an engine that which is compact and which operates at high efficiency.
It is a further object of the present invention to provide a compact and highly efficient engine which provides for heat regeneration and which operates at or near super critical pressure (3,200 lbs.) and high temperature (1,200 degrees Fahrenheit).
It is still a further object of the present invention to provide a highly efficient and compact engine which is environmentally friendly, using external combustion, a cyclone burner and water lubrication.
It is still a further object of the present invention to provide a compact and highly efficient steam engine which has multi-fuel capacity, allowing the engine to burn any of a variety of fuel sources and combinations thereof.
It is yet a further object of the present invention to provide a compact and highly efficient steam engine which is lightweight, with no separate water cooling system and which produces no vibration and no exhaust noise.
It is still a further object of the present invention to provide a compact and highly efficient steam engine which requires no transmission.
These and other objects and advantages of the present invention are more readily apparent with reference to the detailed description and accompanying drawings.
The present invention is directed to a compact and highly efficient engine which uses water as the working fluid, as well as the lubricant. The engine consists primarily of a condenser, a steam generator and a main engine section having valves, cylinders, pistons, pushrods, a main bearing, cams and a camshaft. Ambient air is introduced into the condenser by intake blowers. The air temperature is increased in two phases before entering a cyclone furnace. In the first phase, air enters the condenser from the blowers. In the next phase, the air is directed from the condenser and through heat exchangers where the air is heated prior to entering the steam generator. In the steam generator, the preheated air is mixed with fuel from a fuel atomizer. The burner burns the fuel atomized in a centrifuge, causing the heavy fuel elements to move towards the outer sides of the furnace where they are consumed. The hotter, lighter gasses move through a small tube bundle. The cylinders of the engine are arranged in a radial configuration with the cylinder heads and valves extending into the cyclone furnace. Temperatures in the tube bundle are maintained at 1,200 degrees Fahrenheit. The tube bundle, carrying the steam, is directed through the furnace and exposed to the high temperatures. In the furnace, the steam is super heated and maintained at a pressure up to approximately 3,200 lbs.
Exhaust steam is directed through a primary coil which also serves to preheat the water in the generator. The exhaust steam is then directed through a condenser, in a centrifugal system of compressive condensation, consisting of a stacked arrangement of flat plates. Cooling air circulates through the flat plates, is heated in an exhaust heat exchanger and exits into the furnace. This reheat cycle of air greatly adds to the efficiency and compactness of the engine.
The speed and torque of the engine are controlled by a rocker and cam design which serves to open and close a needle type valve in the engine head. When the valve is opened, high pressure, high temperature steam is injected into the cylinder and allowed to expand as an explosion on the top of the piston high pressure. Use of three or more pistons allows for self-starting.
For a fuller understanding of the nature of the present invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings in which:
Like reference numerals refer to like parts throughout the several views of the drawings.
The present invention is directed to a radial steam engine and is generally indicated as 10 throughout the drawings. Referring initially to
In operation, ambient air is introduced into the condenser 30 by intake blowers 38. The air temperature is increased in two phases before entering a cyclone furnace 22 (referred to hereafter as “combustion chamber”). The condenser 30 is a flat plate dynamic condenser with a stacked arrangement of flat plates 31 surrounding an inner core. This structural design of the dynamic condenser 30 allows for multiple passes of steam to enhance the condensing function. In a first phase, air enters the condenser 30 from the blowers 38 and is circulated over the condenser plates 31 to cool the outer surfaces of the plates and condense the exhaust steam circulating within the plates. More particularly, vapor exiting the exhaust ports 55 of the cylinders 52 passes through the pre-heating coils surrounding the cylinders. The vapor drops into the core of the condenser where centrifugal force from rotation of the crankshaft drives the vapor into the inner cavities of the condenser plates 31. As the vapor changes phase into a liquid, it enters sealed ports on the periphery of the condenser plates. The condensed liquid drops through collection shafts and into the sump 34 at the base of the condenser. A high pressure pump 92 returns the liquid from the condenser sump 34 to the coils 24 in the combustion chamber, completing the fluid cycle of the engine. The stacked arrangement of the condenser plates 31 presents a large surface area for maximizing heat transfer within a relatively compact volume. The centrifugal force of the crankshaft impeller that repeatedly drives the condensing vapor into the cooling plates 31, combined with the stacked plate design, provides a multi-pass system that is far more effective than conventional condensers of single-pass design.
The engine shrouding 12 is an insulated cover that encloses the combustion chamber and piston assembly. The shroud 12 incorporates air transfer ducts 32 that channel air from the condenser 30, where it has been preheated, to the intake portion of air-to-air heat exchangers 42, where the air is further heated. Exiting the heat exchangers 42, this heated intake air enters the atomizer/igniter assemblies in the burner 40 where it is combusted in the combustion chamber. The shroud also includes return ducts that capture the combustion exhaust gases at the top center of the combustion chamber, and leads these gases back through the exhaust portion of the air-to-air heat exchangers 42. The engine shrouding adds to the efficiency and compactness of the engine by conserving heat with its insulation, providing necessary ductwork for the airflow of the engine, and incorporating heat exchangers that harvest exhaust has heat.
Water in its delivery path from the condenser sump pump to the combustion chamber is pumped via through one or more main steam supply lines 21 for each cylinder. The main steam line 21 passes through a pre-heating coil 23 that is wound around each cylinder skirt adjacent to that cylinder's exhaust ports. The vapor exiting the exhaust ports gives up heat to this coil, which raises the temperature of the water being directed through the coil toward the combustion chamber. Reciprocally, in giving up heat to the preheating coils, the exhaust vapor begins the process of cooling on its path through these coils preparatory to entering the condenser. The positioning of these coils adjacent to the cylinder exhaust ports scavenges heat that would otherwise be lost to the system, thereby contributing to the overall efficiency of the engine.
In the next phase, the air is directed through heat exchangers 42 where the air is heated prior to entering the steam generator 20 (see
As the water exits the single line 21 of each individual cylinder's pre-heating coil on its way to the combustion chamber, it branches into the two or more lines 28 per cylinder forming part of the tube bundle which consists of a coiled bundle 24 of all these branched lines 28 for all cylinders, as described above. As seen in
As best seen in
Referring to
Steam under super-critical pressure is admitted to the cylinders 52 of the engine by a mechanically linked throttle mechanism acting on the steam injection needle valve 53. To withstand the 1,200° Fahrenheit temperatures, the needle valves 53 are water cooled at the bottom of their stems by water piped from and returned to the condenser 30 by a water lubrication pump 96. Along the middle of the valve stems, a series of labyrinth seals, or grooves in the valve stem, in conjunction with packing rings and lower lip seals, create a seal between each valve stem and a bushing within which the valve moves. This seals and separates the coolant flowing past the top of the valve stem and the approximate 3,200 lbs. psi pressure that is encountered at the head and seat of each valve. Removal of this valve 53, as well as adjustment for its seating clearance, can be made by threads machined in the upper body of the valve assembly. The needle valve 53 admitting the super-heated steam is positively closed by a spring 82 within each valve rocker arm 80 that is mounted to the periphery of the engine casing. Each spring 82 exerts enough pressure to keep the valve 53 closed during static conditions.
The motion to open each valve is initiated by a crankshaft-mounted cam ring 84. A lobe 85 on the cam ring forces a throttle follower 76 to ‘bump’ a single pushrod 74 per cylinder 52. Each pushrod 74 extends from near the center of the radially configured six cylinder engine outward to the needle valve rocker 80. The force of the throttle follower 76 on the pushrod 74 overcomes the spring closure pressure and opens the valve 53. Contact between the follower, the rocker arm 80, and the pushrod 74 is determined by a threaded adjustment socket mounted on each needle valve rocker arm 80.
Throttle control on the engine is achieved by varying the distance each pushrod 74 is extended, with further extension opening the needle valve a greater amount to admit more super-heated fluid. All six rods 74 pass through a throttle control ring 78 that rotates in an arc, displacing where the inner end of each pushrod 74 rests on the arm of each cam follower (see
Referring to
The normal position for the throttle controller is forward slow speed. As the throttle ring 78 admits steam to the piston, the crank begins to rotate in a slow forward rotation. The long duration of the cam lobe 85 allows for steam admission into the cylinders 52 for a longer period of time. As previously described, the elliptical path of the connecting rods creates a high degree of torque, while the steam admission into the cylinder is for a longer period of time and over a longer lever arm, into the phase of the next cylinder, thereby allowing a self starting movement.
As the throttle ring 78 is advanced, more steam is admitted to the cylinder, allowing an increase in RPM. When the RPM increases, the pump 90 supplies hydraulic pressure to lift the cam ring 84 to high speed forward. The cam ring 84 moves in two phases, jacking up the cam to decrease the cam lobe duration and advance the cam timing. This occurs gradually as the RPM's are increased to a pre-determined position. The shift lever 102 is spring loaded on the shifting rod 104 to allow the sleeve 86 to lift the cam ring 84.
To reverse the engine, it must be stopped by closing the throttle. Reversing the engine is not accomplished by selecting transmission gears, but is done by altering the timing. More specifically, reversing the engine is accomplished by pushing the shift rod 104 to lift the cam sleeve 86 up the crankshaft 60 as the sleeve cam pin 88 travels in a spiraling groove in the cam ring causing the crank to advance the cam past top dead center. The engine will now run in reverse as the piston pushes the crank disk at an angle relative to the crankshaft in the direction of reverse rotation. This shifting movement moves only the timing and not the duration of the cam lobe to valve opening. This will give full torque and self-starting in reverse. High speed is not necessary in reverse.
Exhaust steam is directed through a primary coil which also serves to preheat the water in the generator 20. The exhaust steam is then directed through the condenser 30, in a centrifugal system of compressive condensation. As described above, the cooling air circulates through the flat plates, is heated in an exhaust heat exchanger 42 and is directed into the burner 40. This reheat cycle of air greatly adds to the efficiency and compactness of the engine.
The water delivery requirements of the engine are served by a poly-phase pump 90 that comprises three pressure pump systems. One is a high pressure pump system 92 mounted adjacently within the same housing. A medium pressure pump system 94 supplies the water pressure to activate the clearance volume valve and the water pressure to operate the cam timing mechanism. A lower pressure pump system 96 provides lubrication and cooling to the engine. The high pressure unit pumps water from the condenser sump 34 through six individual lines 21, past the coils of the combustion chamber 22 to each of the six needle valves 53 that provide the super-heated fluid to the power head of the engine. This high pressure section of the poly-phase pump 90 contains radially arranged pistons that closely resemble the configuration of the larger power head of the engine. The water delivery line coming off each of the water pump pistons is connected by a manifold 98 that connects to a regulator shared by all six delivery lines that acts to equalize and regulate the water delivery pressure to the six pistons of the power head. All regulate the water delivery pressure to the six pistons of the power head. All pumping sub units within the poly-phase pump are driven by a central shaft. This pump drive shaft is connected to the main engine crankshaft 60 by a mechanical coupler. When the engine is stopped, an auxiliary electric motor pumps the water, maintaining the water pressure necessary to restarting the engine.
While the present invention has been shown and described in accordance with a preferred and practical embodiment thereof, it is recognized that departures from the instant disclosure are contemplated within the spirit and scope of the present invention.
This application is a continuation application of Co-pending patent application Ser. No. 11/225,422 filed on Sep. 13, 2005, now U.S. Pat. No. 7,080,512, which claimed the benefit of provisional patent application Ser. No. 60/609,725 filed on Sep. 14, 2004.
Number | Name | Date | Kind |
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1636887 | Windell | Jul 1927 | A |
5191858 | McWhorter | Mar 1993 | A |
7080512 | Schoell | Jul 2006 | B2 |
Number | Date | Country | |
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20060254278 A1 | Nov 2006 | US |
Number | Date | Country | |
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60609725 | Sep 2004 | US |
Number | Date | Country | |
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Parent | 11225422 | Sep 2005 | US |
Child | 11489335 | US |