EP0003355A1 - Unidirectional energy converter engine - Google Patents
Unidirectional energy converter engine Download PDFInfo
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- EP0003355A1 EP0003355A1 EP79100216A EP79100216A EP0003355A1 EP 0003355 A1 EP0003355 A1 EP 0003355A1 EP 79100216 A EP79100216 A EP 79100216A EP 79100216 A EP79100216 A EP 79100216A EP 0003355 A1 EP0003355 A1 EP 0003355A1
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- Prior art keywords
- passageway
- pistons
- platform
- region
- energy
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01C—ROTARY-PISTON OR OSCILLATING-PISTON MACHINES OR ENGINES
- F01C1/00—Rotary-piston machines or engines
- F01C1/02—Rotary-piston machines or engines of arcuate-engagement type, i.e. with circular translatory movement of co-operating members, each member having the same number of teeth or tooth-equivalents
- F01C1/063—Rotary-piston machines or engines of arcuate-engagement type, i.e. with circular translatory movement of co-operating members, each member having the same number of teeth or tooth-equivalents with coaxially-mounted members having continuously-changing circumferential spacing between them
Definitions
- thermodynamic cycles such as the Otto, Rankine, and Brayton cycles.
- Most of these systems employ reciprocating pistons; although some, such as those shown in Dutch Patent 65,164 and German Patent 842,845, employ one or more pistons which are forced to travel in one direction in a continuous closed-loop by the expansion of a gaseous medium in one region of the closed loop.
- each piston is coupled to a mechanical element which moves with it, the kinetic energy of the moving piston being converted directly into mechanical energy.
- These systems require complicated mechanisms for coupling the piston or pistons to an associated mechanical element.
- the apparatus for converting a first form of energy into a second form of energy includes a platform carried by support means for rotation about a central axis. At least one continuous, closed-loop passageway is carried by the platform and contains a plurality of freely-movable pistons. Means are provided for applying a force to successive ones of the pistons in a first region of the passageway extending along the periphery of the rotating platform to thereby propel each body in one direction around the passageway and increase its kinetic energy.
- a second region of the passageway which curves inwardly toward the center of the platform the pistons, after being propelled, are caused to work against centrifugal force to thereby convert the kinetic energy of the pistons into potential energy as they approach the center of rotation of the platform.
- centrifugal force acts on the pistons causing them to move radially outwardly back to the first region.
- the energy of the outwardly-moving pistons is converted into rotational energy which is then coupled to the platform to rotate the same.
- each passageway includes two arcuate segments, each having a different radius, and a linear segment . interconnecting the two arcuate segments.
- a rotary union communicates with a duct extending coaxially along a support shaft for the platform; while conduits extend from the duct to the first region of each passageway to supply steam or the like as the expansible fluid from a stationary boiler.
- a second duct can be connected by conduits to each second region of the passageways for exhausting steam therefrom.
- the rotatable means for each passageway includes at least one but preferably two pocketed wheels disposed at opposite sides of the passageway for receiving the pistons as they are moved radially outwardly along the linear regions of the passageways under the influence of centrifugal force. These pocketed wheels also serve to feed the pistons into the first region where they are propelled by expansion of a fluid.
- the pocketed wheels are secured to arbors which are, in turn, rotably supported by the platform and coupled by gears in a stationary gear which is coaxial with the central axis of the platform. The rotational movement of the pocketed wheels is thereby converted into rotational movement of the platform.
- the pocketed wheels at opposite sides of the linear region of the passageway include circumferentially-spaced peripheral pockets to pass the pistons between the wheels.
- the wheels may have spaced-apart magnets on their peripheries, all of the magnets carried by one wheel having magnetic south poles and those carried by the other wheel having magnetic north poles at their respective peripheries.
- liquid fuel is fed from a stationary tank through a coaxial pipeline to the rotating platform.
- An inlet manifold and an exhaust manifold communicate with only part of opposite sides of the aforesaid second arcuate region of each passageway. The remaining part of the second region is used to compress air between the bodies. The compressed air is then fed to a combustion chamber where it is heated and used to propel the pistons in the first region of each passageway.
- a single passageway rather than two, is provided on the rotatable platform.
- the passageway has straight portions on opposite sides of the central axis of rotation of the platform, the straight portions being interconnected at their ends by curved portions, also on opposite sides of the central axis of rotation of the platform.
- Means are provided for applying a force to successive ones of the pistons in one region in each of said straight portions of the passageway to propel them inwardly on the rotating platform against centrifugal force, the pistons being moved radially outwardly in another region of each of the straight portions under centrifugal force.
- the means for converting the energy of the pistons into rotational energy comprises pocketed wheels having their peripheries coinciding with the inner peripheries of the curved portions of the passageway to convert the energy of the pistons in the curved portions, which have been moved outwardly under centrifugal force, into rotational energy.
- these pocketed wheels are coupled through a gear train mounted on the platform which meshes with a stationary gear carried beneath the platform to cause rotation of the platform about its rotational axis.
- the rotating engine shown includes a platform 11 in the form of two disc- shaped plates 11A and 11B (Figs. 3 and 4) with mutually-engaging face surfaces maintained in contact by fastening members, not shown.
- the platform is adapted to rotate about a central vertical axis 12 (Fig. 4) and is secured by fasteners to a centrally-arranged shaft 13 extending downwardly from the bottom of plate 11B of the platform.
- Bearings 14 support the shaft 13 for rotation within a support frame 15.
- a stationary main gear 16 is keyed to a journal surface provided on frame 15. As is perhaps best shown in Figs.
- gear 16 is selec-ed so that it meshes with two separate gear trains, each being identical and including a first idler gear 17 and a second idler gear 18.
- the gears 17, for example, are supported by bearings on arbor shafts 19 (Figs. 4 and 5) carried by plate 11B.
- each idler gear 18 is secured to the lower end of an arbor shaft 20 which extends through an opening in the platform 11.
- the arbor shaft 20 carries a timing gear 21 located within a recess in plate 11B. In this recess, the timing gear 21 meshes with a second timing gear 22 secured to an arbor shaft 23.
- Both arbor shafts 20 and 23 rotate in suitable bearings supported by the platform as shown.
- the uppor ends of arbor shafts 20 and 23 carry pocketed wheels 24 and 25, respectively.
- the pocketed wheels have circular recesses uniformly spaced about their outer periphery which are adapted to received in succession pistons 27 which are typically spheroids.
- Each pair of pocketed wheel assemblies 24, 25 are arranged at generally, diametrically-opposite locations on the platform 11.
- Each pair of pocketed wheels forms part of an independent, unidirectional energy converter loop that includes a continuous, closed-loop passageway 30.
- the two loop passageways take the form of machined slots in each of the mutually-engaging face surfaces of the plates 11A and 11B of the platform 11.
- the passageway 30 is defined by aligned slots having walls which are preferably smooth and formed from metal.
- the passageways are located at mutually-exclusive sectors which lie at opposite sides of a vertical plane passing through the axis 12.
- the pistons 27 are freely-movable bodies which pass in succession through each passageway.
- the tolerances or clearances between the surfaces of the pistons 27 and the walls of the passageway 30 are such as to permit the pistons to move freely therealong. Fluid flow past the pistons within the passageways is sbustan- tially prevented since the pistons have a spherical shape which is substantially complementary to the cross-sectional shape of the passageways. If desired, a tube can be used as a liner in each passageway.
- each passageway 30 is made up of three regions 32, 33 and 34.
- Region 32 extends along the periphery of the platform 11 for a distance of approximately 90°. This region forms an expanding section wherein a fluid medium, such as steam, is used to freely accelerate the pistons in succession.
- Region 33 is curved inwardly toward the center of rotation of the platform 11 and is provided with one or more ports 31 in the upper plate 11A to bleed off fluid between successive pistons. It should be understood, however, that the ports 31 could be replaced by a plenum chamber which collects the steam, condenses and returns it to a boiler.
- Figs. 1 to 5 steam is used for the operation of the rotary platform according to a Rankine cycle.
- the steam is fed from a stationary boiler, not shown, to the rotating platform 11 by means of a duct 40 (Fig. 4) extending through the support shaft 13.
- the steam is delivered by a stationary conduit 41 through a rotary union 42 and into the duct 40.
- Duct 40 communicates with a chamber 43 located in the plate 11B below the continuous, closed-loop passageways 30.
- Radially-extending slots 44 machined into the mutually-engaging face surfaces of plates 11A and 11B, deliver the steam from chamber 43 to supply chambers 45 (see also Figs. 1 and 2).
- bushings 46 Disposed within the chambers 45 are bushings 46 with portal openings to deliver steam from the slots 44 into the expander region 32.
- the expansible steam is injected into the expander region at the point of juncture between the expander region 32 and the radially-extending region 34.
- the force exerted by the expanding steam propels the pistons along the expander region to the point where they enter the combined coasting and steam exhaust section formed by region 33.
- the steam is exhausted through ports 31 to the atmosphere as described above or, if desired, a system of ducts may be used to conduct the steam and/or condensate from region 33 through a pipe within duct 40 in shaft 13 for return to the boiler.
- the steam injected into the expander region 32 will propel each of the pistons 27 along the periphery of the platform 11, thereby converting the thermal energy of the steam into kinetic energy of the pistons 27.
- an equal and opposite reaction is induced tending to rotate the platform in the direction of arrow A.
- the pistons 27 enter the region 33 their direction of movement changes, thereby producing a force on the platform 11 tending to rotate it in a direction opposite to the direction of arrow A.
- the two forces thus produced essentially cancel each other so that, as the pistons are propelled around the passageway 30, the net torque on the platform 11 is essentially zero.
- the gear system just described has two other functions.
- the second function is to maintain the entire rotating system of the rotating energy converter at a desired velocity.
- the third function of the gear system is to feed the pistons into the expander region 32 and provide thrust to overcome frictional drag of the pistons in the loop passageway.
- the two unidirectional energy converter loops according to the invention are disposed at mutually-exclusive sectors which are spaced 180° from each other and supported by the platform 11. While it is possible.to use a single closed-loop passageway, it is obviously preferable to use at least two diametrically-opposed passageways in order that the rotating platform 11 will be balanced rotationally. Furthermore, it will be appreciated that a series of platforms such as that shown herein may be stacked in spaced-apart relation for rotation about a common axis 12.
- a practical engine incorporating the principles of the invention may, for example, employ a three-foot diameter platform having a thickness twice the diameter of the pistons 27.
- the rotating engine may incorporate ten unidirectional energy conversion loops having pistons with diameters of 28,6 mm (1-1/8 inches).
- Such an engine will develop approximately 37 Kilowatt (50 horsepower) while the overall size of the engine will be about 900 mm (three feet) in diameter and about 300 mm (one foot) long, not including ducting for the steam and exhaust.
- the frequency of the pistons in the passageways would be about 100 per second while the platform rotates at a speed of about 650 revolutions per minute.
- Such a concept for a rotating engine has a significant potential for practical low-temperature steam engines based on a 4.5 bar (absolute) (66 psia) at 149 0 C (300 0 F) steam inlet pressure and a 0.2 bar (absolute) (3 psia) at 60°C (140 0 F) steam outlet pressure.
- Fig. 6 illustrates another embodiment of the invention incorporating the principles of the Brayton cycle. Because of the similarity between the parts forming the rotating engine for a Brayton cycle and the parts forming a rotating engine for operation according to the Rankine cycle as just described, elements of Fig. 6 which correspond to those of Fig. 5 are identified by like reference numerals.
- the expander region 32 of each continuous, closed-loop passageway 30 curves along a 90° circumferential part of the platform 11.
- a combined exhaust and intake section 50 receives the pistons from the expander region 32.
- An exhaust manifold 51 delivers the exhaust gases carried between successive pistons. The exhaust gases are replaced by fresh air from an inlet manifold 52. From region 50, the pistons pass into a compression region 53.
- the gases compressed between the pistons are delivered by a manifold 54 at an increased pressure through a check valve 55 and into a combustion chamber 56.
- the compressed air is heated in the combustion chamber and introduced into the unidirectional energy conversion loop by an inlet conduit 57.
- the heated air accelerates the pistons in succession along the expander region 32.
- Liquid fuel is fed from a stationary tank on the rotating platform through a coaxial pipe in shaft 13 with a rotating shaft seal.
- the fuel is then fed by a conduit 58 into the combustion chamber 56.
- the velocity of the piston is at a maximum relative to the unidirectional energy conversion loop formed by its passageway 30.
- the kinetic energy of the piston is thus converted into potential energy as the pistons approach the center of the rotating platform 11 in passing through arcuate regions 50 and 53.
- the kinetic energy of the piston is also expended by compression of air to form the compressed air supply which is fed into the combustion chamber and then, when heated, fed into the expander inlet.
- the pistons apply centrifugal force to the pocketed wheels.
- the mechanical power formed by the unidirectional energy conversion loop is the net centrifugal force imparted to the platform through the sprocket-gear train.
- the second unidirectional energy conversion loop supported by the platform 11 in Fig. 6 is identical to the first and positioned diametrically opposite the first loop. It is again apparent that a series of platforms 11 may be stacked in superimposed spaced-apart relation along the same axis 12.
- the unidirectional energy conversion engine operating according to the Brayton cycle may consist of multiple unidirectional energy conversion loops as was the case with the embodiment of Figs. 1 to 5.
- Figs. 7 and 8 illustrate another embodiment of the invention wherein a single passageway is utilized on a rotating platform rather than two passageways as in the embodiment of Figs 1 to 6. Since many of the parts forming the rotating engine of the embodiment of Figs. 7 and 8 are the same or similar to those of Figs. 1 to 6, certain elements of Figs. 7 and 8 which correspond to those of Figs. 1 to 6 are identified by like reference numerals.
- a platform 100 is provided which rotates about a central axis 102.
- the platform 100 is elongated but symmetrical about the axis of rotation 102 and is, therefore, balanced about the axis of rotation.
- the platform 100 can be formed from upper and lower halves 100A and 100B as shown in Fig. 8.
- Formed in the upper and lower halves 100A and 100B is a single continuous, closed-loop passageway 104 having two straight portions 106 and 108 on opposite sides of the axis of rotation 102.
- the opposite ends of the straight portions 106 and 108 are interconnected by curved portions 110 and 112, respectively, the portons 110 and 112 also being on opposite sides of the axis of rotation 102 of the platform 100.
- opposite sides of the passageway 104 are arranged symmetrically, and balanced, about the axis of rotation 102.
- the platform 100 is generally elliptical in shape, meaning that it is long as compared to its width, having semicircular end portions connected by straight portions.
- the loop passageway 104 is made up of four regions. These comprise a first expander region 114, a first thruster region 116, a second expander region 118 and a second thruster region 120.
- Rotatable thruster wheels 122 and 124 are mounted for rotation on the platform at the respective axes of the two curved end portions 110 and 112 of passageway 104.
- the thruster wheels 122 and 124 are provided with pockets 126, uniformly spaced about their, outer.peripheries, which are adapted to engage successive pistons 27 through the open inner faces of the curved end portions 110 and 112 of the passageway 104. As the pocket thruster wheels 12?
- the rotating thruster wheels also serve to drive the rotating platform 100 and the shaft 13 connected thereto through central, stationary main gear 16 and appropriate idler gears 17 and 17' located beneath the platform 100.
- Idler gears 17 and 17' mesh with gears 18 and 18' connected to the rotatable pocket wheels 122 and 124, respectively, as best shwon in Fig. 8.
- the shaft 13 may be conveniently journaled ' in bearings 130 and 132 as shown in Fig. 8.
- an ideal diatomic gas e.g. air or steam
- a pressure elevated above ambient i.e. from a compressor, boiler or the like
- inlet port 45 located between the second thruster region 120 and the first expander region 114
- inlet port 45' located between the first thruster region 116 and second expander region 118.
- Gas is exhausted from the passageway via a venting port (or ports) 134 located between the first expander region 114 and the first thruster region 116, or via port (or ports) 136 located between the second expander region 118 and the second thruster region 120.
- the pistons 27 act as porting valves at the inlet and venting ports as in the embodiment of Figs. 1 to 6.
- Passageways or slots 44 and 44' can be provided to deliver steam or another expansible fluid from chamber 43, similar to chamber 43 shown in Fig. 4, to the inlet ports 45 and 45'.
- the pressurized gas entering the first expander region 114 through inlet port 45 drives successive pistons 27 through the expander region 114 against the centrifugal force field generated by rotation of the platform 100. That is, the pistons must work against centrifugal force as they approach the center of rotation of platform 100.
- the unit cell of gas between the pistons is closed off from the inlet port 45 and expands adiabatically as the lead piston moves through the expander region.
- the piston ahead of the piston in the expander region 114 traverses venting port 134
- the unit cell of gas ahead of the piston still in the expander region 114 is exhausted through the venting port.
- the piston in the expander region then arrives at the beginning of the thruster region 116 and closes off the venting port 134; while the ensuing piston is driven through the expander region in accordance with the cycle just described.
- the piston Upon leaving the expander region 114, the piston enters the thruster region 116 which is filled with pistons.
- the pistons When the pistons are in the thruster region, in closely-abutting relationship, they are urged toward the curved end portion 112 of the passageway 104 under the influence of centrifugal force. That is, they are urged outwardly in relation to the axis of rotation 102 of the platform 100 by centrifugal force. In this process, they engage the pocketed thruster wheel 124 and impart torque thereto, causing it to rotate with the rotation being transmitted through gears 18' and 17' to central gear 16, thereby causing the entire platform 100 and the drive shaft 13 to rotate in the direction indicated by arrow 128 in bearings 130 and 132 (fig. 8).
- the thruster wheels 122 and 124 rotate, they feed successive ones of the pistons to the expander regions 114 and 118 where the cycle described above is repeated.
- the gear system described above has two other functions. The second function is to maintain the entire rotating system of the rotating energy converter at a desired velocity.
- the third function of the gear system is to feed the pistons into the expander regions 114 and 118 and to provide thrust to overcome frictional drag of the pistons in the loop passageway.
- the rotating passageway 104 of, the embodiment of Figs. 7 and 8 comprises, in series, a first expander region 114, a first thruster region 116, a second expander region 118 and a second thruster region 120.
- each passageway comprises only one expander region and one thruster region.
- this embodiment functions in a manner generally similar to the embodiments previously discussed.
- a starter motor or some other device to initially rotate the platform 100 may be required to initiate centrifugal force on the pistons in regions 116 and 120.
- steam may be used for the operation of the rotating platform 100 in accordance with the Rankine cycle as in the previously- described embodiments.
- the force exerted by the expanding steam which enters the passageway 104 through ports 45 and 45', propels the pistons 27 through the expander regions 114 and 118.
- the steam is exhausted through venting ports 134 and 136 as the pistons enter the thruster regions 116 and 120.
- Venting ports 134 and 13G may be open to the atmosphere or, if desired, a system of ducts, not shown, may be used to return the steam and/or condensate to the boiler in a manner similar to that of Fig. 4.
- compressed gas typically air
- the heated, compressed gas is then introduced into the expander regions from appropriate conduits via the inlet ports. After expansion, the gas is exhausted at ambient pressure via the venting ports 134 and 136 either direct to the atmosphere or through a coaxial duct.
- the compressed gas may be obtained via conventional compressor means, either stationary or rotating in the platform; however, it is preferred to obtain the compressed gas from a separate unidirectional energy converter loop which is rotating about the same axis of rotation (i.e. stacked above or below the platform), and which is adapted to function as a compressor in the manner described in connection with Figs. 7 and 8 hereinafter or as described in U.S. Patent No. 3,859,789, Fawcett et al.
- an expanding gas is provided in the expander regions by way of internal combustion within these regions.
- Compressed air typically from one of the sources described above in reference to the Brayton cycle
- Liquid or gaseous fuel is fed into the expander regions 114 and 118 when the inlet ports are closed off by the pistons leaving the thruster regions.
- Combustion takes place in the expander regions and is cycled to effect expanding gas behind each piston as it enters the expander regions 116 and 120. That is, combustion takes place periodically to propel successive ones of the pistons through the expander regions.
- the combustion gases may be exhausted at ambient pressure via the venting port directly to the atmosphere or through a coaxial duct.
- the operation of the embodiment of Figs. 7 and 8 according to the Otto cycle is similar to that described above regarding the Diesel cycle.
- the fuel and air may be separately introduced into the expander regions, as in the Diesel cycle, or the fuel may be mixed with the incoming air before or after it is compressed. Ignition of the fuel-air mixture is effected in the expander regions 114 and 118 by means of a conventional spark system located in an appropriate recessed area in these regions.
- combustion is cycled to effect expanding gas successively behind each piston as it passes so as to propel successive ones of the pistons through the expander regions.
- the platform 100 shown in Figs. 7 and 8 is rotated by a motor or some other external power source in a direction opposite that shown, gas at ambient pressure will be taken into the passageway 104 via ports 134 and 136 and will be exhausted at an elevated pressure via ports 45 and 45'.
- the system can function as a compressor. If the platform 100 is rotated by a motor, the system of gears interconnecting the thruster wheels 122 and 124 to the central shaft 13 will act to rotate the thruster wheels.
- the rotating thruster wheels will then move the stacked pistons 25 in the thruster regions toward the axis of rotation of the platform, so that upon passing ports 134 and 136, the pistons will travel through the expander regions 114 and 118 under the influencEof centrifugal force.
- the gas between the pistons will be adiabatically compressed by the moving pistons in the expander regions 116 and 120 which would more properly be termed "compressor regions" in this mode. 4
- a series of unidirectional energy converters may be stacked in superimposed, spaced-apart relation for rotation upon shaft 13 about the common axis 102.
- the change-in enthalpy of the gas in the expander regions produces net work, which is performed on the thruster wheels 122 and 124 via the pistons 27, and then transmitted to the rotating platform 100 and the shaft 13;
- the change in enthalpy of the gas in the expander regions transfers energy via the centrifugal field (potential) energy stored in the mass of the pistons as they move through the expander regions from a larger radius of rotation (i.e.
- the gas pressure in the expander region during part of the operating cycle may be below ambient.
- the piston 27A comprises a body having a central annular slot 140 and large diamter end portions 142 and 144 provided with spherically-beveled edges 146 which can engage the periphery of the passageway 104 as the pistons 27A pass around the curved portions 110 and 112.
- the large diameter portions 142 and 144 are hollow as shown.
- the configuration shown in Fig. 9A comprises, in effect, two interconnected pistons separated by the reduced diameter portion 140 which receives the radially, outwardly-projecting prongs on the pocketed wheels 122 and 124 as the pistons move around the curved portions 110 and 112.
- Lightly-loaded piston rings may optionally be located in recesses formed within the outer surface of the pistons, so as to reduce losses due to leakage of the fluid medium around the pistons.
- Fig. 9B is similar to that of Fig. 9A except that the piston 27B in this case comprises two spherical end portions 148 and 150 interconnected by reduced diameter portion 152 which again received the radially, outwardly-projecting prongs on the thruster wheels 122 and 124.
- a piston such as that shown in Fig. 9A, or some other configuration having a cylindrical outer periphery (as contrasted to a sphere) may be preferable in order that the cylindrical surface can more positively close off the ports 134 and 136 as they pass thereby.
- the ports 134 and 136 should be as small in cross section as possible while affording the required flow volume therethrough.
- the embodiments of the invention described above utilize an arrangement wherein the pocketed thruster wheels are mechanically linked (i.e. coupled) to both the rotating platform and the engine drive shaft via a system of gears or drive chains, etc.
- the speed of rotation of the platform is related to the torque produced by the rotating engine of the present invention, whereas the speed of rotation of the thruster wheels is proportional to the rate of torque applied to the engine drive shaft (i.e. shaft power).
- the rotating engine of the present invention can be utilized to produce torque independently from engine drive shaft speed (i.e. high torque can be produced at low or variable speed).
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Abstract
Description
- As is known, systems have been proposed in the past to convert one type of energy into another type by using various thermodynamic cycles, such as the Otto, Rankine, and Brayton cycles. Most of these systems employ reciprocating pistons; although some, such as those shown in Dutch Patent 65,164 and German Patent 842,845, employ one or more pistons which are forced to travel in one direction in a continuous closed-loop by the expansion of a gaseous medium in one region of the closed loop. In the closed-loop systems of the prior art, each piston is coupled to a mechanical element which moves with it, the kinetic energy of the moving piston being converted directly into mechanical energy. These systems, however, require complicated mechanisms for coupling the piston or pistons to an associated mechanical element.
- In U.S. Patent No. 3,859,789, a method and apparatus are disclosed for converting one form of energy into another form of energy through the use of a single continuous, closed-loop passageway containing a plurality of freely-movable, mechanically-unrestrained bodies which travel around the passageway in one direction only. Acceleration of the bodies is effected by means of an expanding fluid medium supplied externally to the closed-loop passageway or by means of internal combustion. The kinetic energy of the bodies is extracted by a variety of methods including causing the propelled bodies, when formed from magnetically-permeable material, to pass through an electromagnetic field to convert some of the kinetic energy into electrical energy. Kinetic energy is also extracted by compressing the fluid between the bodies to provide energy in the form of compressed fluid. When the expansion of a gas is used to propel the bodies in this type of energy converter, the bodies pass through a region where the gas between them is compressed preparatory to a succeeding cycle of operation. In all such prior art systems of this type, the closed-loop passageway itself remains stationary.
- It is an object of the present invention to provide an improved unidirectional energy converter in the form of a rotating engine wherein pistons are accelerated around a closed-loop passageway mounted on a rotating platform. Energy in the form of an expanding gas is converted into kinetic energy which is then converted into potential energy by working the pistons against the centrifugal force of the rotating platform. Finally, the pistons are moved radially outwardly on the platform under the influence of centrifugal force; and their energy is converted into rotational energy which is used to rotate to platform and provide useful work.
- In accordance with one embodiment of the invention, the apparatus for converting a first form of energy into a second form of energy includes a platform carried by support means for rotation about a central axis. At least one continuous, closed-loop passageway is carried by the platform and contains a plurality of freely-movable pistons. Means are provided for applying a force to successive ones of the pistons in a first region of the passageway extending along the periphery of the rotating platform to thereby propel each body in one direction around the passageway and increase its kinetic energy. In a second region of the passageway which curves inwardly toward the center of the platform the pistons, after being propelled, are caused to work against centrifugal force to thereby convert the kinetic energy of the pistons into potential energy as they approach the center of rotation of the platform. In a third, radially-extending region of the passageway centrifugal force acts on the pistons causing them to move radially outwardly back to the first region. In the third region the energy of the outwardly-moving pistons is converted into rotational energy which is then coupled to the platform to rotate the same.
- Prefereable, in the embodiment of the invention just described, there are two closed-loop passageways located at diametrically-opposite locations on the rotating platform. Each passageway includes two arcuate segments, each having a different radius, and a linear segment . interconnecting the two arcuate segments. When the apparatus of the invention is adapted for operation according to the Rankine cycle, a rotary union communicates with a duct extending coaxially along a support shaft for the platform; while conduits extend from the duct to the first region of each passageway to supply steam or the like as the expansible fluid from a stationary boiler. A second duct can be connected by conduits to each second region of the passageways for exhausting steam therefrom. The rotatable means for each passageway includes at least one but preferably two pocketed wheels disposed at opposite sides of the passageway for receiving the pistons as they are moved radially outwardly along the linear regions of the passageways under the influence of centrifugal force. These pocketed wheels also serve to feed the pistons into the first region where they are propelled by expansion of a fluid. The pocketed wheels are secured to arbors which are, in turn, rotably supported by the platform and coupled by gears in a stationary gear which is coaxial with the central axis of the platform. The rotational movement of the pocketed wheels is thereby converted into rotational movement of the platform. Typically, the pocketed wheels at opposite sides of the linear region of the passageway include circumferentially-spaced peripheral pockets to pass the pistons between the wheels. Alternatively, the wheels may have spaced-apart magnets on their peripheries, all of the magnets carried by one wheel having magnetic south poles and those carried by the other wheel having magnetic north poles at their respective peripheries.
- When the aforesaid embodiment of the invention is adapted for operation according to the Brayton cycle, liquid fuel is fed from a stationary tank through a coaxial pipeline to the rotating platform. An inlet manifold and an exhaust manifold communicate with only part of opposite sides of the aforesaid second arcuate region of each passageway. The remaining part of the second region is used to compress air between the bodies. The compressed air is then fed to a combustion chamber where it is heated and used to propel the pistons in the first region of each passageway.
- In another embodiment of the invention, a single passageway rather than two, is provided on the rotatable platform. In this case, the passageway has straight portions on opposite sides of the central axis of rotation of the platform, the straight portions being interconnected at their ends by curved portions, also on opposite sides of the central axis of rotation of the platform. Means are provided for applying a force to successive ones of the pistons in one region in each of said straight portions of the passageway to propel them inwardly on the rotating platform against centrifugal force, the pistons being moved radially outwardly in another region of each of the straight portions under centrifugal force. The means for converting the energy of the pistons into rotational energy comprises pocketed wheels having their peripheries coinciding with the inner peripheries of the curved portions of the passageway to convert the energy of the pistons in the curved portions, which have been moved outwardly under centrifugal force, into rotational energy. As in the previous embodiment, these pocketed wheels are coupled through a gear train mounted on the platform which meshes with a stationary gear carried beneath the platform to cause rotation of the platform about its rotational axis.
- The above and other objects and features of the invention will become apparent from the following detailed description taken in connection with the accompanying drawings which form a part of this specification, and in which:
- Fig. 1 is a plan view of the rotating engine according to one embodiment of the present invention for converting, according to the Rankine cycle, one form of energy into a second form of energy;
- Fig. 2 is an enlarged plan view of the pocketed wheels of the invention for feeding pistons forming part of the apparatus shown in Fig. 1;
- Fig. 3 is a cross-sectional view taken along line III-III of Fig. 2;
- Fig. 4 is a sectional view taken along line IV-IV of Fig. 1;
- Fig. 5 is a sectional view taken along line V-V of Fig. 4;
- Fig. 6 is a plan view similar to Fig. 1 but illustrating the apparatus of the present invention for operation according to the Brayton cycle;
- Fig. 7 is an illustration, in partially broken-away plan view, of another embodiment of the invention wherein a single loop passageway extends around the axis of rotation of a platform, there being two regions in the passageway where pistons are propelled against centrifugal force;
- Fig. 8 is a side view of the embodiment of the invention shown in Fig. 7 and
- Figs. 9A and 9B illustrate alternative forms of the pistons which can be used in the two embodiments of the invention.
- With reference now to Figs. 1 to 5, the rotating engine shown includes a platform 11 in the form of two disc- shaped plates 11A and 11B (Figs. 3 and 4) with mutually-engaging face surfaces maintained in contact by fastening members, not shown. The platform is adapted to rotate about a central vertical axis 12 (Fig. 4) and is secured by fasteners to a centrally-arranged
shaft 13 extending downwardly from the bottom of plate 11B of the platform.Bearings 14 support theshaft 13 for rotation within asupport frame 15. A stationarymain gear 16 is keyed to a journal surface provided onframe 15. As is perhaps best shown in Figs. 1 and 5, the diameter ofgear 16 is selec-ed so that it meshes with two separate gear trains, each being identical and including afirst idler gear 17 and asecond idler gear 18. Thegears 17, for example, are supported by bearings on arbor shafts 19 (Figs. 4 and 5) carried by plate 11B. - As shown in Figs. 2, 3 and 5, each
idler gear 18 is secured to the lower end of anarbor shaft 20 which extends through an opening in the platform 11. Abovegear 18, thearbor shaft 20 carries atiming gear 21 located within a recess in plate 11B. In this recess, thetiming gear 21 meshes with asecond timing gear 22 secured to anarbor shaft 23. Botharbor shafts arbor shafts wheels succession pistons 27 which are typically spheroids. - The respective pairs of
pocketed wheel assemblies loop passageway 30. The two loop passageways take the form of machined slots in each of the mutually-engaging face surfaces of the plates 11A and 11B of the platform 11. In other words, thepassageway 30 is defined by aligned slots having walls which are preferably smooth and formed from metal. The passageways are located at mutually-exclusive sectors which lie at opposite sides of a vertical plane passing through theaxis 12. Thepistons 27 are freely-movable bodies which pass in succession through each passageway. The tolerances or clearances between the surfaces of thepistons 27 and the walls of thepassageway 30 are such as to permit the pistons to move freely therealong. Fluid flow past the pistons within the passageways is sbustan- tially prevented since the pistons have a spherical shape which is substantially complementary to the cross-sectional shape of the passageways. If desired, a tube can be used as a liner in each passageway. - As shown in Fig. 1, each
passageway 30 is made up of threeregions Region 32 extends along the periphery of the platform 11 for a distance of approximately 90°. This region forms an expanding section wherein a fluid medium, such as steam, is used to freely accelerate the pistons in succession.Region 33 is curved inwardly toward the center of rotation of the platform 11 and is provided with one or more ports 31 in the upper plate 11A to bleed off fluid between successive pistons. It should be understood, however, that the ports 31 could be replaced by a plenum chamber which collects the steam, condenses and returns it to a boiler. - As the
pistons 27 move radially inwardly in theregion 33, they must work against centrifugal force; and in this process the kinetic energy of the moving pistons inregion 32 is converted into potential energy as they approach the center of rotation of the platform. Finally, when the pistons are inregion 34 in closely-abutting relationship, they are urged radially outwardly under the influence of centrifugal force. In this process, they pass through the pocketedwheels central gear 16, thereby causing the entire platform 11 and the elements carried threby to rotate in the direction indicated by the arrow A in Fig. 1. As the pocketedwheels pistons 27 to the first orexpander region 32 where they again are propelled in the same direction as the direction of rotation of the platform 11. - In Figs. 1 to 5, steam is used for the operation of the rotary platform according to a Rankine cycle. The steam is fed from a stationary boiler, not shown, to the rotating platform 11 by means of a duct 40 (Fig. 4) extending through the
support shaft 13. The steam is delivered by astationary conduit 41 through arotary union 42 and into theduct 40.Duct 40 communicates with achamber 43 located in the plate 11B below the continuous, closed-loop passageways 30. Radially-extendingslots 44, machined into the mutually-engaging face surfaces of plates 11A and 11B, deliver the steam fromchamber 43 to supply chambers 45 (see also Figs. 1 and 2). Disposed within thechambers 45 arebushings 46 with portal openings to deliver steam from theslots 44 into theexpander region 32. As shown, the expansible steam is injected into the expander region at the point of juncture between theexpander region 32 and the radially-extendingregion 34. The force exerted by the expanding steam propels the pistons along the expander region to the point where they enter the combined coasting and steam exhaust section formed byregion 33. Inregion 33, the steam is exhausted through ports 31 to the atmosphere as described above or, if desired, a system of ducts may be used to conduct the steam and/or condensate fromregion 33 through a pipe withinduct 40 inshaft 13 for return to the boiler. - In the operation of the invention, the steam injected into the
expander region 32 will propel each of thepistons 27 along the periphery of the platform 11, thereby converting the thermal energy of the steam into kinetic energy of thepistons 27. As each of thepistons 27 is propelled forwardly, an equal and opposite reaction is induced tending to rotate the platform in the direction of arrow A. However, as thepistons 27 enter theregion 33, their direction of movement changes, thereby producing a force on the platform 11 tending to rotate it in a direction opposite to the direction of arrow A. The two forces thus produced essentially cancel each other so that, as the pistons are propelled around thepassageway 30, the net torque on the platform 11 is essentially zero. As the pistons pass throughregion 33 and work against centrifugal force, their kinetic energy is converted into potential energy as they enter the radially-extendingregion 34. Now, and assuming that the platform 11 is rotated, the abuttingpistons 27 inregion 34 will be urged radially outwardly by centrifugal force; and as they pass through the pocketedwheels gears stationary gear 16. The energy of the pistons, which are urged radially outwardly by centrifugal force inregion 34, is thus converted into rotational energy used to drive the platform 11 in the direction of arrow A as shown in Fig. 1. It will be appreciated that a starter motor or some other device to initially rotate the platform may be required to initiate centrifugal force on the pistons inregion 34. - In addition to converting the energy of the pistons into rotational energy, the gear system just described has two other functions. The second function is to maintain the entire rotating system of the rotating energy converter at a desired velocity. The third function of the gear system is to feed the pistons into the
expander region 32 and provide thrust to overcome frictional drag of the pistons in the loop passageway. - The two unidirectional energy converter loops according to the invention are disposed at mutually-exclusive sectors which are spaced 180° from each other and supported by the platform 11. While it is possible.to use a single closed-loop passageway, it is obviously preferable to use at least two diametrically-opposed passageways in order that the rotating platform 11 will be balanced rotationally. Furthermore, it will be appreciated that a series of platforms such as that shown herein may be stacked in spaced-apart relation for rotation about a
common axis 12. - A practical engine incorporating the principles of the invention may, for example, employ a three-foot diameter platform having a thickness twice the diameter of the
pistons 27. The rotating engine may incorporate ten unidirectional energy conversion loops having pistons with diameters of 28,6 mm (1-1/8 inches). Such an engine will develop approximately 37 Kilowatt (50 horsepower) while the overall size of the engine will be about 900 mm (three feet) in diameter and about 300 mm (one foot) long, not including ducting for the steam and exhaust. Under these circumstances, the frequency of the pistons in the passageways would be about 100 per second while the platform rotates at a speed of about 650 revolutions per minute. Such a concept for a rotating engine has a significant potential for practical low-temperature steam engines based on a 4.5 bar (absolute) (66 psia) at 1490C (3000F) steam inlet pressure and a 0.2 bar (absolute) (3 psia) at 60°C (1400F) steam outlet pressure. - Fig. 6 illustrates another embodiment of the invention incorporating the principles of the Brayton cycle. Because of the similarity between the parts forming the rotating engine for a Brayton cycle and the parts forming a rotating engine for operation according to the Rankine cycle as just described, elements of Fig. 6 which correspond to those of Fig. 5 are identified by like reference numerals. The
expander region 32 of each continuous, closed-loop passageway 30 curves along a 90° circumferential part of the platform 11. A combined exhaust andintake section 50 receives the pistons from theexpander region 32. Anexhaust manifold 51 delivers the exhaust gases carried between successive pistons. The exhaust gases are replaced by fresh air from aninlet manifold 52. Fromregion 50, the pistons pass into acompression region 53. The gases compressed between the pistons are delivered by a manifold 54 at an increased pressure through acheck valve 55 and into acombustion chamber 56. The compressed air is heated in the combustion chamber and introduced into the unidirectional energy conversion loop by aninlet conduit 57. The heated air accelerates the pistons in succession along theexpander region 32. Liquid fuel is fed from a stationary tank on the rotating platform through a coaxial pipe inshaft 13 with a rotating shaft seal. The fuel is then fed by aconduit 58 into thecombustion chamber 56. - As each piston exits from the
expander region 32 in succession, the velocity of the piston is at a maximum relative to the unidirectional energy conversion loop formed by itspassageway 30. The kinetic energy of the piston is thus converted into potential energy as the pistons approach the center of the rotating platform 11 in passing througharcuate regions region 34 of the passageway, the pistons apply centrifugal force to the pocketed wheels. The mechanical power formed by the unidirectional energy conversion loop is the net centrifugal force imparted to the platform through the sprocket-gear train. - The second unidirectional energy conversion loop supported by the platform 11 in Fig. 6 is identical to the first and positioned diametrically opposite the first loop. It is again apparent that a series of platforms 11 may be stacked in superimposed spaced-apart relation along the
same axis 12. Thus, the unidirectional energy conversion engine operating according to the Brayton cycle may consist of multiple unidirectional energy conversion loops as was the case with the embodiment of Figs. 1 to 5. - Figs. 7 and 8 illustrate another embodiment of the invention wherein a single passageway is utilized on a rotating platform rather than two passageways as in the embodiment of Figs 1 to 6. Since many of the parts forming the rotating engine of the embodiment of Figs. 7 and 8 are the same or similar to those of Figs. 1 to 6, certain elements of Figs. 7 and 8 which correspond to those of Figs. 1 to 6 are identified by like reference numerals.
- In the rotating unidirectional energy converter shown in Figs. 7 and 8, a
platform 100 is provided which rotates about a central axis 102. Theplatform 100 is elongated but symmetrical about the axis of rotation 102 and is, therefore, balanced about the axis of rotation. Theplatform 100 can be formed from upper andlower halves 100A and 100B as shown in Fig. 8. Formed in the upper andlower halves 100A and 100B is a single continuous, closed-loop passageway 104 having twostraight portions straight portions curved portions portons platform 100. Thus, opposite sides of thepassageway 104 are arranged symmetrically, and balanced, about the axis of rotation 102. Theplatform 100 is generally elliptical in shape, meaning that it is long as compared to its width, having semicircular end portions connected by straight portions. Instead of forming thepassageway 104 from upper andlower plates 100A and 100B, it is also possible to form the passageway from a tube which is rigidly mounted on a rotatable platform, not shown. Other forms of construction will be readily apparent to those skilled in the art. - The
loop passageway 104 is made up of four regions. These comprise a first expander region 114, afirst thruster region 116, asecond expander region 118 and asecond thruster region 120.Rotatable thruster wheels curved end portions passageway 104. Thethruster wheels pockets 126, uniformly spaced about their, outer.peripheries, which are adapted to engagesuccessive pistons 27 through the open inner faces of thecurved end portions passageway 104. As thepocket thruster wheels 12? and 124 rotate, they serve to move successive pistons through thecurved end portions respective expander regions 114 and 118. The rotating thruster wheels also serve to drive the rotatingplatform 100 and theshaft 13 connected thereto through central, stationarymain gear 16 and appropriate idler gears 17 and 17' located beneath theplatform 100. Idler gears 17 and 17', in turn, mesh withgears 18 and 18' connected to therotatable pocket wheels pocket wheels shaft 13 to cause it and theplatform 100 connected thereto to rotate in the direction ofarrow 128. Theshaft 13 may be conveniently journaled'inbearings - In the operation of the embodiment shown in Figs. 7 and 8, an ideal diatomic gas (e.g. air or steam) at a pressure elevated above ambient (i.e. from a compressor, boiler or the like) is introduced into the
passageway 104 viainlet port 45 located between thesecond thruster region 120 and the first expander region 114, and via inlet port 45' located between thefirst thruster region 116 andsecond expander region 118. Gas is exhausted from the passageway via a venting port (or ports) 134 located between the first expander region 114 and thefirst thruster region 116, or via port (or ports) 136 located between thesecond expander region 118 and thesecond thruster region 120. Thepistons 27 act as porting valves at the inlet and venting ports as in the embodiment of Figs. 1 to 6. Passageways orslots 44 and 44' can be provided to deliver steam or another expansible fluid fromchamber 43, similar tochamber 43 shown in Fig. 4, to theinlet ports 45 and 45'. - The pressurized gas entering the first expander region 114 through
inlet port 45 drivessuccessive pistons 27 through the expander region 114 against the centrifugal force field generated by rotation of theplatform 100. That is, the pistons must work against centrifugal force as they approach the center of rotation ofplatform 100. When the next piston closes off theinlet port 45, the unit cell of gas between the pistons is closed off from theinlet port 45 and expands adiabatically as the lead piston moves through the expander region. When the piston ahead of the piston in the expander region 114traverses venting port 134, the unit cell of gas ahead of the piston still in the expander region 114 is exhausted through the venting port. The piston in the expander region then arrives at the beginning of thethruster region 116 and closes off the ventingport 134; while the ensuing piston is driven through the expander region in accordance with the cycle just described. - Upon leaving the expander region 114, the piston enters the
thruster region 116 which is filled with pistons. When the pistons are in the thruster region, in closely-abutting relationship, they are urged toward thecurved end portion 112 of thepassageway 104 under the influence of centrifugal force. That is, they are urged outwardly in relation to the axis of rotation 102 of theplatform 100 by centrifugal force. In this process, they engage the pocketedthruster wheel 124 and impart torque thereto, causing it to rotate with the rotation being transmitted through gears 18' and 17' tocentral gear 16, thereby causing theentire platform 100 and thedrive shaft 13 to rotate in the direction indicated byarrow 128 inbearings 130 and 132 (fig. 8). The energy of the pistons, which are urged outwardly by centrifugal force inregions - As the
thruster wheels expander regions 114 and 118 where the cycle described above is repeated. In addition to converting the energy of thepistons 27 into rotational energy, the gear system described above has two other functions. The second function is to maintain the entire rotating system of the rotating energy converter at a desired velocity. The third function of the gear system is to feed the pistons into theexpander regions 114 and 118 and to provide thrust to overcome frictional drag of the pistons in the loop passageway. - It can thus be seen that the
rotating passageway 104 of, the embodiment of Figs. 7 and 8 comprises, in series, a first expander region 114, afirst thruster region 116, asecond expander region 118 and asecond thruster region 120. This is in contrast to the embodiments shown in Figs. 1 to 6 wherein each passageway comprises only one expander region and one thruster region. However, except as noted above, this embodiment functions in a manner generally similar to the embodiments previously discussed. A starter motor or some other device to initially rotate theplatform 100 may be required to initiate centrifugal force on the pistons inregions - In the embodiment shown in Figs. 7 and 8, steam may be used for the operation of the
rotating platform 100 in accordance with the Rankine cycle as in the previously- described embodiments. When steam is used, the force exerted by the expanding steam, which enters thepassageway 104 throughports 45 and 45', propels thepistons 27 through theexpander regions 114 and 118. The steam is exhausted through ventingports thruster regions ports 134 and 13G may be open to the atmosphere or, if desired, a system of ducts, not shown, may be used to return the steam and/or condensate to the boiler in a manner similar to that of Fig. 4. - While the rotating engine as shown in Figs. 7 and 8 may operate in accordance with the thermodynamic principles of the Rankine cycle as described above, this embodiment of the invention, appropriately modified, m=y also function in accordance with the principles of the Brayton, Diesel, or Otto cycles as briefly described below.
- In the operation of the embodiment of Figs. 7 and 8 according to the Brayton cycle, compressed gas (typically air) is heated in a combustion chamber rotating on the platform as in Fig. 6, or by a heat exchanger rotating on the platform, with the heat exchanger being connected to a stationary external heat source via a coaxial duct. The heated, compressed gas is then introduced into the expander regions from appropriate conduits via the inlet ports. After expansion, the gas is exhausted at ambient pressure via the venting
ports - In the operation of the embodiment of Figs. 7 and 8 in accordance with the principles of the Diesel cycle, an expanding gas is provided in the expander regions by way of internal combustion within these regions. Compressed air (typically from one of the sources described above in reference to the Brayton cycle) is introduced into the regions via the
inlet ports 45 and 45'. Liquid or gaseous fuel is fed into theexpander regions 114 and 118 when the inlet ports are closed off by the pistons leaving the thruster regions. Combustion takes place in the expander regions and is cycled to effect expanding gas behind each piston as it enters theexpander regions - The operation of the embodiment of Figs. 7 and 8 according to the Otto cycle is similar to that described above regarding the Diesel cycle. The fuel and air may be separately introduced into the expander regions, as in the Diesel cycle, or the fuel may be mixed with the incoming air before or after it is compressed. Ignition of the fuel-air mixture is effected in the
expander regions 114 and 118 by means of a conventional spark system located in an appropriate recessed area in these regions. As in the Diesel cycle, combustion is cycled to effect expanding gas successively behind each piston as it passes so as to propel successive ones of the pistons through the expander regions. - If the
platform 100 shown in Figs. 7 and 8 is rotated by a motor or some other external power source in a direction opposite that shown, gas at ambient pressure will be taken into thepassageway 104 viaports ports 45 and 45'. In this regard, the system can function as a compressor. If theplatform 100 is rotated by a motor, the system of gears interconnecting thethruster wheels central shaft 13 will act to rotate the thruster wheels. The rotating thruster wheels will then move thestacked pistons 25 in the thruster regions toward the axis of rotation of the platform, so that upon passingports expander regions 114 and 118 under the influencEof centrifugal force. The gas between the pistons will be adiabatically compressed by the moving pistons in theexpander regions - It will also be appreciated that a series of unidirectional energy converters may be stacked in superimposed, spaced-apart relation for rotation upon
shaft 13 about the common axis 102. In the embodiment of Figs. 7 and 8 the following general observations can be made: (1) the change-in enthalpy of the gas in the expander regions produces net work, which is performed on thethruster wheels pistons 27, and then transmitted to therotating platform 100 and theshaft 13; (2) the change in enthalpy of the gas in the expander regions transfers energy via the centrifugal field (potential) energy stored in the mass of the pistons as they move through the expander regions from a larger radius of rotation (i.e. about the axes of rotation of the platform 100) to a smaller radius of rotation (i.e. nearer the axis of rotation); (3) the initial and final velocities of the pistons traveling in the expander regions relative to the rotating platform are equal; and (4) the inlet and venting gas port sizes, the mass of the pistons, the speed of rotation of the thruster wheels and the platform, and the inlet and exit states of the gas are all interrelated in the operation of, and the net work produced in, this system. Under some conditions of operation, the gas pressure in the expander region during part of the operating cycle may be below ambient. - In Figs. 9A and 9B, alternative forms of the
pistons 27 are shown. In Fig. 9A, thepiston 27A comprises a body having a centralannular slot 140 and largediamter end portions 142 and 144 provided with spherically-bevelededges 146 which can engage the periphery of thepassageway 104 as thepistons 27A pass around thecurved portions large diameter portions 142 and 144 are hollow as shown. The configuration shown in Fig. 9A comprises, in effect, two interconnected pistons separated by the reduceddiameter portion 140 which receives the radially, outwardly-projecting prongs on the pocketedwheels curved portions - Lightly-loaded piston rings (not shown) may optionally be located in recesses formed within the outer surface of the pistons, so as to reduce losses due to leakage of the fluid medium around the pistons.
- Fig. 9B is similar to that of Fig. 9A except that the piston 27B in this case comprises two
spherical end portions reduced diameter portion 152 which again received the radially, outwardly-projecting prongs on thethruster wheels - A piston such as that shown in Fig. 9A, or some other configuration having a cylindrical outer periphery (as contrasted to a sphere) may be preferable in order that the cylindrical surface can more positively close off the
ports ports - The embodiments of the invention described above utilize an arrangement wherein the pocketed thruster wheels are mechanically linked (i.e. coupled) to both the rotating platform and the engine drive shaft via a system of gears or drive chains, etc. In an alternative preferred embodiment of the invention it may be desirable to decouple the thruster wheels from the platform, and to provide a separate, external drive motor which can be utilized to separately drive the rotating platform at a speed of rotation which is independent from that of the pocketed thruster wheels. It is apparent that the speed of rotation of the platform is related to the torque produced by the rotating engine of the present invention, whereas the speed of rotation of the thruster wheels is proportional to the rate of torque applied to the engine drive shaft (i.e. shaft power). By providing a separate drive motor to independently drive the platform, the rotating engine of the present invention can be utilized to produce torque independently from engine drive shaft speed (i.e. high torque can be produced at low or variable speed).
- Although the invention has been shown in connection with certain specific embodiments, it will be readily apparent to those skilled in the art that various changes in form and arrangement of parts may be made to suit requirements without departing from the spirit and scope of the invention.
Claims (32)
Applications Claiming Priority (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US87284878A | 1978-01-27 | 1978-01-27 | |
US872848 | 1978-01-27 | ||
US241179A | 1979-01-11 | 1979-01-11 | |
US2411 | 1979-01-11 |
Publications (2)
Publication Number | Publication Date |
---|---|
EP0003355A1 true EP0003355A1 (en) | 1979-08-08 |
EP0003355B1 EP0003355B1 (en) | 1982-05-26 |
Family
ID=26670342
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP19790100216 Expired EP0003355B1 (en) | 1978-01-27 | 1979-01-25 | Unidirectional energy converter engine |
Country Status (4)
Country | Link |
---|---|
EP (1) | EP0003355B1 (en) |
JP (1) | JPS54112432A (en) |
CA (1) | CA1099526A (en) |
DE (1) | DE2962937D1 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
FR2462916A1 (en) * | 1979-08-01 | 1981-02-20 | Dynamit Nobel Ag | ROTATIONAL FORCE GENERATING ELEMENT, ESPECIALLY FOR SAFETY BELTS TIGHTENING DEVICES |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2014075177A1 (en) * | 2012-11-19 | 2014-05-22 | Richard Arel | Power transmission assembly and method for transmitting power |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
NL65164C (en) * | ||||
DE842645C (en) * | 1944-11-12 | 1952-06-30 | Hans Alwin Gantikow | Power machine with rotating piston and abutment slide |
US3859789A (en) * | 1972-01-31 | 1975-01-14 | Battelle Development Corp | Method and apparatus for converting one form of energy into another form of energy |
-
1979
- 1979-01-25 EP EP19790100216 patent/EP0003355B1/en not_active Expired
- 1979-01-25 DE DE7979100216T patent/DE2962937D1/en not_active Expired
- 1979-01-26 CA CA320,358A patent/CA1099526A/en not_active Expired
- 1979-01-26 JP JP810279A patent/JPS54112432A/en active Pending
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
NL65164C (en) * | ||||
DE842645C (en) * | 1944-11-12 | 1952-06-30 | Hans Alwin Gantikow | Power machine with rotating piston and abutment slide |
US3859789A (en) * | 1972-01-31 | 1975-01-14 | Battelle Development Corp | Method and apparatus for converting one form of energy into another form of energy |
US3927329A (en) * | 1972-01-31 | 1975-12-16 | Battelle Development Corp | Method and apparatus for converting one form of energy into another form of energy |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
FR2462916A1 (en) * | 1979-08-01 | 1981-02-20 | Dynamit Nobel Ag | ROTATIONAL FORCE GENERATING ELEMENT, ESPECIALLY FOR SAFETY BELTS TIGHTENING DEVICES |
US4444010A (en) * | 1979-08-01 | 1984-04-24 | Dynamit Nobel Aktiengesellschaft | Rotary power element |
Also Published As
Publication number | Publication date |
---|---|
JPS54112432A (en) | 1979-09-03 |
EP0003355B1 (en) | 1982-05-26 |
CA1099526A (en) | 1981-04-21 |
DE2962937D1 (en) | 1982-07-15 |
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