The invention relates generally to rotary internal combustion engines. In particular, the invention relates to internal combustion engines using a rotor, valves and chambers absent the use of a piston.
Internal combustion engines that employ spinning rotors instead of linearly translating pistons date back to the nineteenth century, including a concept by Joseph Webb (British Patent 1216). Other than Felix Wankel's design (U.S. Pat. No. 2,988,008), few have seen commercial success, in contrast to various piston-driven types.
Conventional rotary internal combustion engines yield disadvantages addressed by various exemplary embodiments of the present invention. In particular, various exemplary embodiments describe a housing with chambers accessible by pivoting flap valves (also called vanes). In particular, exemplary embodiments provide a pivoting flap valve for an internal combustion rotary that produces mechanical torque while the valve oscillates. The engine includes an annular planar housing with a substantially circular annulus flanked by first and second cavities, an axial shaft, a rotor disposed on the shaft and rotating within the annulus. The valve is disposed within one cavity of said cavities and includes an arc wedge and a pivot shaft. The wedge has outer convex surface and an inner concave surface and a shaft hole between and parallel to the surfaces along a rocking axis. The pivot shaft passes through the shaft hole that enables the wedge to rock back and forth within the cavity in the annular planar housing without interference with the cam block. Each valve includes indents to pass around fore and aft circular wings on a rotor.
These and various other features and aspects of various exemplary embodiments will be readily understood with reference to the following detailed description taken in conjunction with the accompanying drawings, in which like or similar numbers are used throughout, and in which:
In the following detailed description of exemplary embodiments of the invention, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration specific exemplary embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. Other embodiments may be utilized, and logical, mechanical, and other changes may be made without departing from the spirit or scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims.
The disclosure generally employs quantity units with the following abbreviations: length in centimeters (cm) and meters (m), mass in grams (g) or kilograms (kg), time in seconds (s), angles in degrees)(°, force in newtons (N), temperature in kelvins (K), energy in joules (J), and frequencies in gigahertz (GHz). Supplemental measures can be derived from these, such as density in grams-per-cubic-centimeters (g/cm3), moment of inertia in gram-square-centimeters (kg-m2) and the like.
A rotary engine increases power over a conventional reciprocating internal combustion engine by constantly spinning in the same direction without piston reversals. Additionally, a rotary engine comprises fewer parts thus reducing weight and simplifying manufacturing. Exemplary embodiments leverage these principles to deliver a high power to weight engine for all power generation needs. In particular, the exemplary rotary engine increases power over other rotary engines combining strokes, sharing space, and spinning in constant circle, without variation, aiding mechanical motion and sealing.
In particular, various exemplary embodiments provide higher power density due to combined strokes, shared space, and rotor stacking, fewer losses due to elimination of energy consuming piston reversals, improved fuel economy due to turning any number of equivalent cylinders on and off without losses, lighter weight due to elimination of counterweights at each piston, reduced weight and ease of manufacture due to elimination of cam-shaft for valve operation, ease of manufacture due to elimination of numerous components, reduced cost due to ease of manufacture and elimination of numerous parts, Increased reliability and maintainability due to simplicity of design.
True circular motion, higher power density due to combustion in the direction of rotation and potential for more equivalent cylinders in the same space, better fuel economy due to combustion in the direction of rotation and turning any number of equivalent cylinders on and off, elimination of warping due to combustion at two (or more) locations. In particular, various exemplary embodiments describe a housing with chambers accessible by flap valves. In particular, exemplary embodiments provide an internal combustion rotary engine for producing mechanical torque. The engine includes an annular planar housing, a rotor, optional sparkplugs, flap valves, an axial shaft and fore-and-aft covers. The housing includes a quadrilateral symmetry including a substantially circular annulus flanked by first and second cavities.
The rotor has a cam block sandwiched between fore and aft circular wings. The sparkplugs are respectively accessible to the second cavities. The flap valves rock within the respective cavities and within the cam block. Each valve includes indents to pass around the wings. The fuel intake provides fuel to the cavities. The axial shaft rotates the rotor within the housing. Covers, each having a center orifice and a pair of ports exposed to ambient and respectively adjacent the first and second cavities. The wings intermittently block at least one port while the rotor spins about the shaft.
A similar set of angularly spaced cutouts 340, 350 extend in from the opposite side of the rotor 130 that aligns with spaces associated with the aft wing 320. An aft angularly extending volumetric space 360 is defined between the cam face 310 and the outer rim formed by the aft wing 320. A fore angularly extending volumetric space 370 is defined between the cam face 310 and the outer rim formed by the fore wing 330.
The second configuration 520 illustrates the rotor 140 at top dead center with the marker 540 just after six o'clock. Both valves 160 are flush with the rotor surface 310. The upper cavity 140 stores compressed gas, while the lower cavity 150 is effectively vacuous. In the third configuration 530, the exhaust from the power stroke of configuration 510 pushes out the upper window 240 on the aft cover 170 while the compressed air at the upper cavity 140 ignites and produces a power stroke in volume 360. Meanwhile, the rotor 130 draws fresh intake air into volume 370 through the lower window 250 on the aft cover 170 and concurrently compresses the air in volume 370 into the lower cavity 150. Note that wings 320 and 330 open and close the upper window 240 and lower window 250 as respective intake and exhaust ports as they sweep past.
The rotary engine generates power by spinning a rotor 130 (or 630, 1430) inside a housing 120 (or 620, 1420). The housing is closed by two covers 170, 220 that bolt to the housing 120. There are exhaust and intake ports as upper and lower windows 240, 250 in the covers 170, 220. Within the housing 120 is the rotor 130 and two flap valves 160 (or 660, 1460). The assembly forms a unique 4-stroke engine (intake, compression, power and exhaust). The rotor 130 spins on its shaft 230 when a compressed fuel-air mixture ignites, and the resulting combustion forces the flap valve 160 open and drives the rotor 130 clockwise in a power-stroke. Exhaust, intake and compression occur in similar manner. Before attempting to describe the four strokes, some salient features about the rotor 130 and flap valve 160 are provided.
The rotor 130 has a central oblong cam shape 310 with two wings 320 and 330. The cam shaft 230 protrudes axially from the rotor 610. One should note that a hollow-shaft rotor is quite possible. The purpose of the wings 320, 330 is to alternately block the intake and exhaust windows 240, 250 in both covers 170, 220. The flap valve 160 functions to direct the flow of the following: the fuel-air mixture in through the intake window 240 during intake, the fuel-air into the combustion cavity 150 during compression, the combustion products out of the combustion cavity 150 during the power stroke, and the exhaust gases out of the exhaust window 250 during the exhaust stroke.
The flap valve 160 toggles back and forth to create a barrier against which all four strokes operate. The cam follower edges 460 of the flap valve 160 are in contact with the rotor cam surface 310 while spinning. Clearance is required between the flap valve 160 and the rotor wings 320, 330.
The following configurations 510, 520 and 530 illustrate the four strokes. Using view 500 and an analog clock face for reference, intake occurs between twelve o'clock and one o'clock (approximately configuration 510) when the rotor 130 travels past the flap valve 160 so as to expose the upper window 240 as the intake port in front cover 220. The upper window 240 directly opposite the intake on the aft cover 170 is the exhaust port and closes via the rotor wing 330. The fuel-air mixture is drawn into the space 370 created by the rotor cam surface 310, rotor wing 330, inner housing wall 1040, and covers 170, 220. Meanwhile, the spent gasses from the previous power stroke are pushed out the upper window 240 as the exhaust port at six o'clock (configuration 520) contemporaneous with the next power stroke begins at seven o'clock and a fresh volume of fuel-air mix is being compressed at eleven o'clock.
By the end of the stroke at six o'clock (in configuration 520), the rotor 130 is blocking both upper and lower windows 240, 250 (as respective intake and exhaust ports), the flap valves 160 pivot back to the neutral position, and the space 370 is entirely filled with the fuel-air mixture. All of the exhaust gasses are expelled from the lower window 250 as the exhaust port, and the rotor 130 has sealed that window 250 as well. The fuel-air mix drawn into the space 370 is ready to be compressed for compression into the lower cavity 150 while the compressed gasses in the upper cavity 140 are ready to be ignited and drive the rotor 130 around. The exhaust gases that fill the left portion of the upper cavity 140 will be pushed out the upper window 240 as the exhaust port.
While certain features of the embodiments of the invention have been illustrated as described herein, many modifications, substitutions, changes and equivalents will now occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the embodiments.
The invention is a Continuation, claims priority to and incorporates by reference in its entirety U.S. patent application Ser. No. 16/668,530 filed Oct. 30, 2019 and assigned Navy Case 105803, which pursuant to 35 U.S.C. § 119, the benefit of priority from provisional application 62/828,595 with filing date Apr. 3, 2019, is claimed for this non-provisional application.
The invention described was made in the performance of official duties by one or more employees of the Department of the Navy, and thus, the invention herein may be manufactured, used or licensed by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.
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1028316 | Allyn | Jun 1912 | A |
1701534 | Knopp | Feb 1929 | A |
2116897 | Jay | May 1938 | A |
2988008 | Wankel | Jun 1961 | A |
3913534 | Bratten | Oct 1975 | A |
3924976 | Hinckley | Dec 1975 | A |
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4860704 | Slaughter | Aug 1989 | A |
5305721 | Burtis | Apr 1994 | A |
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Number | Date | Country | |
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62828595 | Apr 2018 | US |
Number | Date | Country | |
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Parent | 16668530 | Oct 2019 | US |
Child | 17172865 | US |