US1602018A - Internal-combustion rotary engine - Google Patents

Internal-combustion rotary engine Download PDF

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Publication number
US1602018A
US1602018A US658917A US65891723A US1602018A US 1602018 A US1602018 A US 1602018A US 658917 A US658917 A US 658917A US 65891723 A US65891723 A US 65891723A US 1602018 A US1602018 A US 1602018A
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rotor
pocket
blades
cylinders
ring
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US658917A
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Harvey Thomas
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02BINTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
    • F02B57/00Internal-combustion aspects of rotary engines in which the combusted gases displace one or more reciprocating pistons
    • F02B57/08Engines with star-shaped cylinder arrangements
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02BINTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
    • F02B1/00Engines characterised by fuel-air mixture compression
    • F02B1/02Engines characterised by fuel-air mixture compression with positive ignition
    • F02B1/04Engines characterised by fuel-air mixture compression with positive ignition with fuel-air mixture admission into cylinder
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T74/00Machine element or mechanism
    • Y10T74/18Mechanical movements
    • Y10T74/18056Rotary to or from reciprocating or oscillating
    • Y10T74/18296Cam and slide

Definitions

  • My invention is an improved internal combustion rotary engine.
  • the object 'of my invention is to provide an engine which is simple in construction and eflicient in operation.
  • Another object of my engine is to compress the mixture in various cylinders in the rotor, and then inject it into the explosion chamber on the periphery of the rotor, thereby getting a plurality of explosions; i. e., one for each cylinder.
  • Figure 1 is a longitudinal sectional view of my engine.
  • Figure 2 is a sectional view taken on the line 22 of Figure 1.
  • Figure 3 is a sectional-view taken on the line 3-3 of Figure 1.
  • Figure 4 is a side view of the intake ring.
  • Figure 5 is a sectional view taken on the line 55 of Figure 4.
  • Figure 6 is a side view of one of the stationary side members.
  • my engine consists of two stationary side plates 1 and 2 which are spaced by a circumferential ring 3, and a rotor 4 adapted to rotate between said plates.
  • the plates 1 and 2 are suitably secured to the ring 3, as with cap screws 5.
  • the rotor 4 is keyed to a shaft 6, which is journaled in bearings 7 and 8 in the plates 1 and 2 respectively.
  • a plurality of radially positioned cylinders 9 are formed in the rotor 4, and pistons 10 are adapted to reciprocate in said cylinders.
  • Pitmen 11 are secured to the pistons 10 and are bent at right angles to enter an eccentric groove 12' in the plate 2.
  • the pitmen 11 enter bearings 13 which rotate in the groove 12.
  • pitmen 11 and pistons 10 will reciprocate an amount corresponding to the eccentricity of the groove 12.
  • a plate 14 is secured to each of the pitmen 11 adjacent the bearings 13 and bears against the plate 2, thus reinforcing the pitman against twisting out of proper alignment.
  • the explosivemixture which is formed in the carburetor 15 is drawn through a port 16 in the plate 1 into the intake chamber 17 in said plate.
  • An intake ring 18 fits with n the chamber 17 and rotates with the rotor 4.
  • This ring has an annular groove 19 cut 9 on the downward stroke of the pistons 10,
  • arcuate block 22 is formed in the chamber 17, the urpose of which is to close the ports 20 on tile u ward stroke of the piston.
  • the block 22 ts within the groove 19 and bears against the bottom of said groove, thus effectually closing the ports 20 and permitting the piston to compress the mixture in the cylinder.
  • Rings 23--23 and 24-24 are set in the outer and inner face respectively of the intake ring 18 and bear against the plate 1 and rotor 4 respectively to prevent any leakage of gases around the ring.
  • Blades 25 are slidably mounted in guides 26 between each pair of cylinders 9 1n the .rotor 4. The ob ect of these blades is to form a firing chamber around each cylinder 9. A firing pocket 27 is formed in the inner face of the ring, andv the blades 25 are moved outwardly into this pocket to form a wall against which the expanding gases push to rotate the rotor 4. Each of the blades 25 has a yieldable scraper plate 28 set in the end thereof, against springs 29. As theblades arrive at'the ed e of the pocket 27 they are moved upward y therein to form a gas tight seal in the following manner: Pins 30 project from the bottom ofthe blades 25 into a cam groove 31 in the plate 1.
  • Bearings 32 are positioned on the pins 30 and travel in the groove 31.
  • a cam 33 is formed of the oove 31 which corresponds to the pocket 2?, and as the pins 30 arrive at the cam they are moved upwardly which projects the blades into the pocket.
  • the cam 33 is substantially the same height as the depth of the pocket 27.
  • Compression chambers 34 are formed in the blades 25, and ports 35 are formed in the rotor 4 and extend from the top of the cylinders 9 to the bottom of the chambers 34, when the blades are in the normal position. Ports 36 are formed in the rotor 4 and extend through the periphery thereof,
  • a spark plug 37 is set in the ring 3 and plug 37 at the proper intervals, depending on the number of cylinders in the rotor 4.
  • a scraper plate 41 is positioned in the ring 3 at the entering end of the pocket 27 and presses against the rotor 4, thus preventing the escape of gas from the pocket.
  • the operation of my invention is as follows: Taking a cylinder after it has passed the pocket 27, the piston 10 is moving downwards, and drawing gases from the chamber 17 through the port 21 into the cylinder 9. As the piston starts to move upwardly block 22 closes the port 21 and the gas is compressed. The blades 25 being in their normal position the port 35 opens into the chamber 34 and the gases are compressed therein. As the blades 25 reach the pocket 27, they are moved upwardly away from the port 35 and open the port 36 which allows the compressed gas to enter the pocket and it is ignited by the plug 37. The expanding gas presses against the blade 25 and rotates the rotor 4.
  • An engine comprising a rotor, bearings in which said rotor is mounted, a stationary ring, said ring having a firing pocket formed therein, cylinders in said rotor, pistons in said cylinders, means to reciprocate said pistons, blades in said rotor, stationary side plates, one of said plates having a cam groove formed therein, a pin formed on said blades and adapted to project into said groove, whereby said blade is moved into the pocket, said blades having a compression chamber formed therein, said blades being provided with by-passes to conduct the compressed gas to said chamber, and means to conduct the compressed gas to the firing pocket from said chamber when the blade is projected into the pocket, and means to fire the gas in said pocket.
  • An engine comprising a rotor, a stationary ring having a firing pocket formed therein, a plurality of cylinders within said rotor, pistons adapted to reciprocate therein, a radiall movable blade for each cylinder, said bla e having a compression chamber therein, said compression chamber being.
  • An engine comprising a rotor, a stationary ring having a firing pocket formed therein, cylinders within said rotor, a piston within each cylinder, said rotor being provided with by-passes thru which combustible gases are conducted to the cylinders on the suction stroke of the pistons, radially movable blades carried by said rotor each of which is provided with a compression chamher, said rotor being provided with ports communicating with the outer ends of said cylinders and in communication with said compression chambers on the compression stroke of said piston, means whereby said blades are moved outwardly when the pocket is reached and ports carried by said rotor and communicating with said pocket and also communicating with said compression chambers when the blades project into the pocket.
  • An engine comprising a rotor, a stationary ring having a firing pocket formed therein, cylinders carried by said rotor, a piston within each cylinder, stationary side walls supporting said stationary ring, one of said walls being provided with an annular intake chamber, an intake ring within said intake chamber, said intake ring being provided with an annular groove and intake ports communicating with said annular groove, an arcuate block located within said intake chamber and extending for approximately 180 degrees, said arcuate block being adapted to close said intake ports on the compression strokes of said pistons, said rotor being provided with ports communicating with said intake chamber and with the upper ends of said cylinders so that said cylinders will be in communication with said intake chamber unless said intake ports are closed by said block, the other wall adapted to support said ring being provided with an eccentric groove, pitmen extending from said piston to said last mentioned groove so that as said-pistons reciprocate, said rotor will be rotated.
  • An engine comprising a rotor, a sta tionary ring having a firing pocket formed therein, a plurality of cylinders within said rotor. pistons adapted to reciprocate therein, a radially movable blade for each cylinder, said blade having a compression chamber therein, said compression chamber being adapted to communicate with said pocket when the upper end of said blade is within said pocket and to communicate with one of the cylinders for the remaining part of its rotation, and, pitman means whereby the outer ends of said blades are at all times pushed against the inner periphery of said stationary ring.
  • An engine comprising a rotor, a stationary ring having a firing pocket formed therein, a plurality of cyhnders within said rotor, pistons adapted to reciprocate therein, a radially movable blade for each cylinder, said blade having a compression chamber therein, said compression chamber being adapted to communicate with said pocket when the upper end of said blade is within said pocket and to communicate with one of the cylinders for the remaining part of its rotation and pitman means whereby the outer ends of said blades are at all times pushed against the inner periphery of said stationary ring, said last mentioned means comprising a pin carried by each blade and projecting into a cam groove within one of the side walls of said stationary ring.
  • An engine comprising a rotor, astationary ring having a firing pocket formed therein, a plurality of cylinders within said rotor. pistons adaptedto reciprocate therein, a radially movable blade for each cylinder, said blade having a compression chamber therein, said compression chamber being adapted to communicate with said pocket when the upper end of said blade is within said pocketand to communicate with one of the cylinders f or the remaining part of its rotation and pitman means whereby the outer ends of said blades are at all times pushed against the inner periphery of said stationary ring, said last mentioned means comprising a pin carried by each blade and projecting into a cam groove within one of the side walls of said stationary ring, said cam groove being of the same configuration as the inner periphery of said stationary ring.
  • An engine comprising a rotor mounted in bearings, a stator surrounding said rotor and provided with a firing recess, cylinders in said rotor, pistons in said cylinders, means to reciprocate said pistons, recip-' rocable blades in the rotor between the respective cylinders, guides for said blades, stationary side plates enclosing said cylinders and blades, one of said side plates having a cam groove on its inner face, means on said blades-coacting with said cam groove to move the blades into said firing recess, 'said blades having a compression chamber and communicating by-passes formed therein, and means forming passageways in the guides, blades and peripheral portion of the rotor adapted to establish communication between the firing recess and the closed end of the cylinder when the blades are respectively projected into said firing recess.

Description

Oct. 5, 1926. I 1,602,018
T. HARVEY INTERNAL COMBUSTION ROTARY ENGINE Filed August 25, 1923 4 Sheets-Sheet 1 INVENTOR 77/0Mfl5 f/HEVEY ATTORNEY INTERNAL COMBUSTION ROTARY ENGI NE Filed August 23. 1923 4 Sheets-Sheet 2 INVENTOR THO/M95 HfiEI/Ef giwmw ATTORNEY Oct. 5 1926. 1,602,018
T. HARVEY INTERNAL COMBUSTION ROTARY ENGINE Filed August 23 1923 4 Sheets-Sheet 4 G I ATTORNEY PATENT OFFICE.
THOMAS HARVEY, OF BERKELEY, CALIFORNIA.
INTERNAL-COMBUSTION ROTARY ENGINE.
Application filed August 23, 1923. Serial No. 658,917.
My invention is an improved internal combustion rotary engine.
The object 'of my invention is to provide an engine which is simple in construction and eflicient in operation.
Another object of my engine is to compress the mixture in various cylinders in the rotor, and then inject it into the explosion chamber on the periphery of the rotor, thereby getting a plurality of explosions; i. e., one for each cylinder.
In the annexed drawing I have shown the preferred form of my invention, but it may also be embodied in other forms, and in this application I wish to cover my invention in whatever form it may be embodied.
Referring to the drawings:
Figure 1 is a longitudinal sectional view of my engine.
Figure 2 is a sectional view taken on the line 22 of Figure 1.
Figure 3 is a sectional-view taken on the line 3-3 of Figure 1.
Figure 4 is a side view of the intake ring.
Figure 5 is a sectional view taken on the line 55 of Figure 4.
Figure 6 is a side view of one of the stationary side members.
Referring more particularly to the drawing, my engine consists of two stationary side plates 1 and 2 which are spaced by a circumferential ring 3, and a rotor 4 adapted to rotate between said plates. The plates 1 and 2 are suitably secured to the ring 3, as with cap screws 5. The rotor 4 is keyed to a shaft 6, which is journaled in bearings 7 and 8 in the plates 1 and 2 respectively.
A plurality of radially positioned cylinders 9 are formed in the rotor 4, and pistons 10 are adapted to reciprocate in said cylinders. Pitmen 11 are secured to the pistons 10 and are bent at right angles to enter an eccentric groove 12' in the plate 2. The pitmen 11 enter bearings 13 which rotate in the groove 12. As the rotor 4 rotates the bearings 13, pitmen 11 and pistons 10 will reciprocate an amount corresponding to the eccentricity of the groove 12. A plate 14 is secured to each of the pitmen 11 adjacent the bearings 13 and bears against the plate 2, thus reinforcing the pitman against twisting out of proper alignment. The explosivemixture which is formed in the carburetor 15 is drawn through a port 16 in the plate 1 into the intake chamber 17 in said plate. An intake ring 18 fits with n the chamber 17 and rotates with the rotor 4.
This ring has an annular groove 19 cut 9 on the downward stroke of the pistons 10,
through the ports 20 and 21 from the chamber 17. This intake occurs during the entire downward stroke of the piston 10. A 180 degree. arcuate block 22 is formed in the chamber 17, the urpose of which is to close the ports 20 on tile u ward stroke of the piston. The block 22 ts within the groove 19 and bears against the bottom of said groove, thus effectually closing the ports 20 and permitting the piston to compress the mixture in the cylinder. Rings 23--23 and 24-24 are set in the outer and inner face respectively of the intake ring 18 and bear against the plate 1 and rotor 4 respectively to prevent any leakage of gases around the ring.
Blades 25 are slidably mounted in guides 26 between each pair of cylinders 9 1n the .rotor 4. The ob ect of these blades is to form a firing chamber around each cylinder 9. A firing pocket 27 is formed in the inner face of the ring, andv the blades 25 are moved outwardly into this pocket to form a wall against which the expanding gases push to rotate the rotor 4. Each of the blades 25 has a yieldable scraper plate 28 set in the end thereof, against springs 29. As theblades arrive at'the ed e of the pocket 27 they are moved upward y therein to form a gas tight seal in the following manner: Pins 30 project from the bottom ofthe blades 25 into a cam groove 31 in the plate 1. Bearings 32 are positioned on the pins 30 and travel in the groove 31. A cam 33 is formed of the oove 31 which corresponds to the pocket 2?, and as the pins 30 arrive at the cam they are moved upwardly which projects the blades into the pocket. The cam 33 is substantially the same height as the depth of the pocket 27.
Compression chambers 34 are formed in the blades 25, and ports 35 are formed in the rotor 4 and extend from the top of the cylinders 9 to the bottom of the chambers 34, when the blades are in the normal position. Ports 36 are formed in the rotor 4 and extend through the periphery thereof,
and When the blades 25 are'in their raised position the port is opened into the top of the chambers 34 to permit the gas to flow into the entering end of the pocket 27.
A spark plug 37 is set in the ring 3 and plug 37 at the proper intervals, depending on the number of cylinders in the rotor 4. A scraper plate 41 is positioned in the ring 3 at the entering end of the pocket 27 and presses against the rotor 4, thus preventing the escape of gas from the pocket.
The operation of my invention is as follows: Taking a cylinder after it has passed the pocket 27, the piston 10 is moving downwards, and drawing gases from the chamber 17 through the port 21 into the cylinder 9. As the piston starts to move upwardly block 22 closes the port 21 and the gas is compressed. The blades 25 being in their normal position the port 35 opens into the chamber 34 and the gases are compressed therein. As the blades 25 reach the pocket 27, they are moved upwardly away from the port 35 and open the port 36 which allows the compressed gas to enter the pocket and it is ignited by the plug 37. The expanding gas presses against the blade 25 and rotates the rotor 4.
Having described my invention I claim:
1. An engine comprising a rotor, bearings in which said rotor is mounted, a stationary ring, said ring having a firing pocket formed therein, cylinders in said rotor, pistons in said cylinders, means to reciprocate said pistons, blades in said rotor, stationary side plates, one of said plates having a cam groove formed therein, a pin formed on said blades and adapted to project into said groove, whereby said blade is moved into the pocket, said blades having a compression chamber formed therein, said blades being provided with by-passes to conduct the compressed gas to said chamber, and means to conduct the compressed gas to the firing pocket from said chamber when the blade is projected into the pocket, and means to fire the gas in said pocket.
2. An engine comprising a rotor, a stationary ring having a firing pocket formed therein, a plurality of cylinders within said rotor, pistons adapted to reciprocate therein, a radiall movable blade for each cylinder, said bla e having a compression chamber therein, said compression chamber being.
adapted to communicate with said pocket when the upper end of said blade is within said pocket and to communicate with one of the cylinders for the remaining part of its rotation.
3. An engine comprising a rotor, a stationary ring having a firing pocket formed therein, cylinders within said rotor, a piston within each cylinder, said rotor being provided with by-passes thru which combustible gases are conducted to the cylinders on the suction stroke of the pistons, radially movable blades carried by said rotor each of which is provided with a compression chamher, said rotor being provided with ports communicating with the outer ends of said cylinders and in communication with said compression chambers on the compression stroke of said piston, means whereby said blades are moved outwardly when the pocket is reached and ports carried by said rotor and communicating with said pocket and also communicating with said compression chambers when the blades project into the pocket.
4. An engine comprising a rotor, a stationary ring having a firing pocket formed therein, cylinders carried by said rotor, a piston within each cylinder, stationary side walls supporting said stationary ring, one of said walls being provided with an annular intake chamber, an intake ring within said intake chamber, said intake ring being provided with an annular groove and intake ports communicating with said annular groove, an arcuate block located within said intake chamber and extending for approximately 180 degrees, said arcuate block being adapted to close said intake ports on the compression strokes of said pistons, said rotor being provided with ports communicating with said intake chamber and with the upper ends of said cylinders so that said cylinders will be in communication with said intake chamber unless said intake ports are closed by said block, the other wall adapted to support said ring being provided with an eccentric groove, pitmen extending from said piston to said last mentioned groove so that as said-pistons reciprocate, said rotor will be rotated.
5. An engine comprising a rotor, a sta tionary ring having a firing pocket formed therein, a plurality of cylinders within said rotor. pistons adapted to reciprocate therein, a radially movable blade for each cylinder, said blade having a compression chamber therein, said compression chamber being adapted to communicate with said pocket when the upper end of said blade is within said pocket and to communicate with one of the cylinders for the remaining part of its rotation, and, pitman means whereby the outer ends of said blades are at all times pushed against the inner periphery of said stationary ring.
. 6. An engine comprising a rotor, a stationary ring having a firing pocket formed therein, a plurality of cyhnders within said rotor, pistons adapted to reciprocate therein,a radially movable blade for each cylinder, said blade having a compression chamber therein, said compression chamber being adapted to communicate with said pocket when the upper end of said blade is within said pocket and to communicate with one of the cylinders for the remaining part of its rotation and pitman means whereby the outer ends of said blades are at all times pushed against the inner periphery of said stationary ring, said last mentioned means comprising a pin carried by each blade and projecting into a cam groove within one of the side walls of said stationary ring.
7. An engine comprising a rotor, astationary ring having a firing pocket formed therein, a plurality of cylinders within said rotor. pistons adaptedto reciprocate therein, a radially movable blade for each cylinder, said blade having a compression chamber therein, said compression chamber being adapted to communicate with said pocket when the upper end of said blade is within said pocketand to communicate with one of the cylinders f or the remaining part of its rotation and pitman means whereby the outer ends of said blades are at all times pushed against the inner periphery of said stationary ring, said last mentioned means comprising a pin carried by each blade and projecting into a cam groove within one of the side walls of said stationary ring, said cam groove being of the same configuration as the inner periphery of said stationary ring.
8. An engine comprising a rotor mounted in bearings, a stator surrounding said rotor and provided with a firing recess, cylinders in said rotor, pistons in said cylinders, means to reciprocate said pistons, recip-' rocable blades in the rotor between the respective cylinders, guides for said blades, stationary side plates enclosing said cylinders and blades, one of said side plates having a cam groove on its inner face, means on said blades-coacting with said cam groove to move the blades into said firing recess, 'said blades having a compression chamber and communicating by-passes formed therein, and means forming passageways in the guides, blades and peripheral portion of the rotor adapted to establish communication between the firing recess and the closed end of the cylinder when the blades are respectively projected into said firing recess.
In testimony whereof I aflix my signature.
THOMAS HARVEY.
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Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3118432A (en) * 1960-08-05 1964-01-21 Horace Tomasello Rotary internal combustion engine
US3168082A (en) * 1960-09-29 1965-02-02 Villiers Joseph E De Rotary engines
US3175360A (en) * 1961-01-03 1965-03-30 Glenn Thomas Lane Peripheral closed chamber engine
US3398727A (en) * 1967-02-01 1968-08-27 Vincent Rotary Engines Ltd Rotary internal combustion engines
US3527262A (en) * 1968-04-16 1970-09-08 Jerry C Fuchs Rotating piston chamber engine
US3851630A (en) * 1972-10-19 1974-12-03 Marine Ind Inc Rotary piston engine
FR2572770A1 (en) * 1984-11-02 1986-05-09 Aase Jan M ROTARY INTERNAL COMBUSTION ENGINE
US20050260091A1 (en) * 2004-05-20 2005-11-24 Staffend Gilbert S Rotary device for use in an engine
US9850759B2 (en) 2013-01-03 2017-12-26 Wb Development Company Llc Circulating piston engine

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3118432A (en) * 1960-08-05 1964-01-21 Horace Tomasello Rotary internal combustion engine
US3168082A (en) * 1960-09-29 1965-02-02 Villiers Joseph E De Rotary engines
US3175360A (en) * 1961-01-03 1965-03-30 Glenn Thomas Lane Peripheral closed chamber engine
US3398727A (en) * 1967-02-01 1968-08-27 Vincent Rotary Engines Ltd Rotary internal combustion engines
US3527262A (en) * 1968-04-16 1970-09-08 Jerry C Fuchs Rotating piston chamber engine
US3851630A (en) * 1972-10-19 1974-12-03 Marine Ind Inc Rotary piston engine
FR2572770A1 (en) * 1984-11-02 1986-05-09 Aase Jan M ROTARY INTERNAL COMBUSTION ENGINE
WO1986002698A1 (en) * 1984-11-02 1986-05-09 Aase Jan M Rotary two-stroke internal combustion engine
GB2181488A (en) * 1984-11-02 1987-04-23 Aase Jan M Rotary two-stroke internal combustion engine
US4688531A (en) * 1984-11-02 1987-08-25 Aase Jan M Rotary internal combustion engine
US20050260091A1 (en) * 2004-05-20 2005-11-24 Staffend Gilbert S Rotary device for use in an engine
US7556015B2 (en) 2004-05-20 2009-07-07 Staffend Gilbert S Rotary device for use in an engine
US9850759B2 (en) 2013-01-03 2017-12-26 Wb Development Company Llc Circulating piston engine

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