The present invention relates to engines, and more particularly to rotary engines.
Rotary engines have promise of high efficiencies, high power densities and low part count, which have attracted numerous engineers and efforts to this filed. Among great many configurations existing in the prior art, one of the simplest and the most promising is based on the gerotor concept. With reference to
Having very few moving parts it is not surprising that this simple design has attracted attention of many who attempted to design a rotary engine around it. The major problem that could be traced to all rotary engines, however, is difficulty in sealing the working fluid during the compression, combustion and expansion strokes of the engines. While theoretically most of the engines look feasible on paper, since they completely encompass working fluid without using seals, in practice, when machining tolerances and thermal expansion are taken into account and also when parts are starting to wear out, the sealing of working fluid is not possible without seals. The most famous version of gerotor-based engine and the only one used in production is the Wankel engine, in which 3-lobe rotor moves inside of 2-lobe housing, as shown in
1. Relatively high degree of leakage, despite the seal grid. For example, the bouncing of fast-moving apex seals, as well as holes into the engine to accommodate spark plug(s), contribute to leakage.
2. Large seal travel.
3. High thermal losses caused by very high surface to volume ratio of the combustion chamber at the moment of highest compression.
4. Low geometrically achievable compression ratio.
5. Necessity to meter oil into the working chamber to lubricate the apex seals, which can't get lubrication by any other means, and the existence of ports through which this oil is exhausted, causing emission problems.
Theoretically gerotor engines with a stationary outer rotor have just one major moving part—the rotor. This rotor, moving inside a housing, forms variable geometry cavities that contract and expand in a course of rotor's rotation. The sealing is accomplished by theoretical line contact between the rotor and the housing; such a contact is to occur at least in two places. In general, the gerotors are designed to have very small sliding contact between the rotor and the housing, though, attempts were made to implement “rolling without sliding”—see U.S. Pat. No. 7,520,738 to Katz as an example of such an effort. Another example is described in U.S. Pat. No. 5,373,819 to Rene Linder, which uses rollers in conjunction with an eccentric to guide a rotor within the housing. Yet another example is described in Russian patent RU 2078221 C1 to Veselovsky, which uses seals within a housing. In practice, as stated above, manufacturing tolerances and thermal expansion cause designers to leave a relatively large gap between the rotor and the housing or rotor and rollers. If housing and rotor are inflexible or if rollers can't accommodate for the thermal expansion or the preload due to machining tolerance, the sealing can't be accomplished. So, it becomes meaningless to talk about purely rolling contact between rotor and the housing. This gap has to be closed one way or another by the seal to enable a workable engine.
In a first embodiment of the invention there is provided an improved engine of the type including a cycloidal rotor having N lobes and a housing having a corresponding set of N+1 lobe-receiving regions for successively receiving the lobes as the rotor rotates about an axis relative to the housing, the housing having (i) a pair of sides axially disposed on first and second sides of the rotor, and (ii) a peak disposed between each pair of adjacent lobe-receiving regions, and (iii) an intake port and an exhaust port, wherein the improvement is defined by: a plurality of peak seals, at least one of the plurality of peak seals disposed on each peak and configured to maintain contact with the rotor throughout a period of rotation of the rotor, each seal being radially biased against the rotor throughout the rotation of the rotor, on account of the cycloidal geometry of the rotor and the lobe-receiving portions; a first passageway defined in the rotor to communicate cyclically between the intake port and a working chamber, the working chamber defined as a volume lying between two peak seals, the housing and the rotor; a second passageway, distinct from the first passageway, defined in the rotor to communicate cyclically between the exhaust port and the working chamber; a first face seal disposed between the first side and the rotor; a second face seal disposed between the second side and the rotor; wherein the passageways and the seals are configured to cause each seal to maintain contact with both the rotor and one of the sides through all angular positions of the rotor while avoiding communication with either of the ports.
In another embodiment, each peak seal has a contact region with the rotor, and the contact region is curved with a radius of curvature equal to the radius of curvature of a theoretical roller, which theoretical roller is uniquely defined by the geometry of the rotor and the geometry of the lobe-receiving regions.
In another embodiment, the rotor has a first axial face, a second axial face parallel to the first axial face, and a radial surface between the first axial face and the second axial face, and normal to, the first axial face and the second axial face, and wherein the first axial face and the radial face define a first edge of the rotor and the second axial face and the radial face define a second edge of the rotor, and wherein the first face seal is disposed at the first edge of the rotor.
In an further embodiment, the second face seal is disposed at the second edge of the rotor.
In another embodiment, the rotor has a first axial face, a second axial face parallel to the first axial face, and a radial surface between, and normal to, the first axial face and the second axial face, and wherein the first axial face and the radial face define a first edge of the rotor, and wherein the first face seal is disposed on the first axial face displaced from the first edge of the rotor, so as to define a first annular landing on the first axial face between the first edge and the first face seal, the engine further comprising and a button seal disposed so as to contact the rotor and the first face seal at the first annular landing.
In another embodiment, at a first angle of the rotor within the housing the working chamber forms a compression chamber having a maximum compression chamber volume, and at a second angle of the rotor within the housing the working chamber forms an expansion chamber having a maximum expansion chamber volume, the maximum expansion chamber volume being at greater than or equal to 1.0 times the maximum compression chamber volume.
In another embodiment, the maximum expansion chamber volume is at least 3 times the maximum compression chamber volume.
Another embodiment further includes a plurality of lubricant channels in at least one of the sides, each of the plurality of the lubricant channels disposed so as to deliver lubricant to a corresponding one of the plurality of peak seals.
Another embodiment further includes a lubricant channel in at least one of the sides, the lubricant channel disposed so as to continuously deliver lubricant to a corresponding one of the face seals.
In another embodiment is an improved engine of the type including a rotor having N lobes and a housing having a corresponding set of N+1 lobe-receiving regions for successively receiving the lobes as the rotor rotates about its axis and orbits about an axis relative to the housing, the housing having (i) a pair of sides axially disposed on first and second sides of the rotor, and (ii) a peak disposed between each pair of adjacent lobe-receiving regions, and (iii) an intake port and an exhaust port, wherein the improvement includes: a first passageway defined in the rotor to communicate cyclically between the intake port and a working chamber defined as a volume lying between two peak seals, the housing and the rotor; a second passageway, distinct from the first passageway, defined in the rotor to communicate cyclically between the exhaust port and the working chamber; a sealing grid comprising a plurality of peak seals, at least one of the plurality of peak seals disposed on each peak and configured to maintain contact with the rotor, such seal being radially biased against the rotor; and one of: a face seal disposed on the rotor and configured to maintain contact with the sides of the housing such seal being axially biased against the housing side, where over the course of rotation the face seal does not cross over the intake or exhaust port, and 2×(N+1) button seals, one for each side of every peak, disposed within the housing side, axially biased toward the rotor and configured to maintain contact with the peak seal and the face seal, and a face seal disposed on the rotor and configured to maintain contact with the sides of the housing and a chamfered portion of the rotor, such face seal being axially biased against the housing side; wherein the ports, passageways and face seal are configured to cause the face seal to maintain contact with both the rotor and one of the sides of the housing through all angular positions of the rotor while avoiding said seal crossing over either of the ports.
In another embodiment, the face seal is a wire seal.
In another embodiment, the face seal is disposed at an edge of the rotor, which edge is defined by the intersection of an axial face of the rotor with a radial face of the rotor.
In another embodiment, the profile of the face seal is generated as a cycloidal curve in which the radius of the theoretical roller used to generate the cycloidal curve is the radius of the button in the button seal.
In another embodiment, the rotor is of a cycloidal geometry defined by a set of N+1 theoretical rollers, and each peak seal has a contact region with the rotor, and the contact region is curved with a radius of curvature approximating a radius of curvature of the theoretical roller that the peak seal replaces.
Another embodiment includes a housing having a working cavity, and a combustion chamber in fluid communication with the working cavity; a piston disposed on the housing and configured to controllably enter into and withdraw from the combustion chamber; a rotor rotatably mounted within the working cavity, so as to form a working chamber of variable volume with the housing, at different angles of rotation of the rotor within the working cavity; and a controller synchronized to the angle of rotation of the rotor to controllably cause the piston to enter into and withdraw from the combustion chamber, so as to cause the combined volume of the working chamber and the combustion chamber to be constant over a range of angles of rotation of the rotor.
Another embodiment includes a housing having a working cavity; a shaft, the shaft having an eccentric portion; a rotor having a first axial face, and a second axial face opposite the first axial face, the rotor disposed on the eccentric portion and within the working cavity, the rotor comprising a first cam on the first axial face, the first cam having an eccentricity corresponding to the eccentricity of the eccentric portion of the shaft; and a cover integral with, or fixedly attached to, the housing, the cover comprising a plurality or rollers, each roller engaged with the cam, wherein the cam guides the rotation of the rotor as the rotor rotates within the working cavity and orbits around the shaft.
Another embodiment includes a second cam on the second axial face of the rotor.
The foregoing features of embodiments will be more readily understood by reference to the following detailed description, taken with reference to the accompanying drawings, in which:
Various embodiments provide improved rotary engines that operate at higher efficiency, with lower exhaust emissions, than traditional piston or rotary engines. These characteristics allow improved fuel efficiency, and also make engines more environmentally friendly than traditional rotary engines, such as the Wankel rotary engine, for example, as used for decades by the Mazda corporation.
Unlike previous internal combustion engines, illustrative embodiments use a cycloid (or cycloidal) rotor that rotates within a fixed housing.
As used in this description and the accompanying claims, the following terms shall have the meanings indicated, unless the context otherwise requires:
Cycloidal: The term “cycloidal” refers to the geometry of a rotor in some embodiments of a rotary engine. The rotor (which may be described as a “cycloid disk”) has Z1 number of lobes. The rotor geometry is generated based on Z2 theoretical rollers, where Z2=Z1+1, and the theoretical rollers have radius Rr and are located a distance R away from a central point.
The rotor (cycloid disk) profile may be mathematically generated using equations derived by Shin and Kwon [see Shin, J. H., and Kwon, S. M., 2006, “On the Lobe Profile Design in a Cycloid Reducer Using Instant Velocity Center,” Mech. Mach. Theory, 41, pp. 596-616]:
A rotary engine or even a rotary compressor can be built using this geometry for any Z1 from 1 to infinity. For example, various embodiments described below have rotors in which Z1=2 and Z2=3, with an understanding that any Z1 could be used as well and that the application is not limited to engines but is also applicable to compressors, pumps and hydraulic or pneumatic motors.
Maximum volume of a compression chamber: the maximum volume of a compression chamber is the volume of the compression chamber (which is a working chamber at that phase of an engine cycle when working medium within the working chamber is fresh, e.g., air, and is being compressed prior to combustion) at the point in the engine cycle when the chamber is first cut off from the environment outside of the engine. For example, in the engine 200, the maximum volume of the compression chamber is the volume of that chamber just after the intake passage has been eclipsed so that there is no longer a fluid passage from the compression chamber to the environment outside of the engine housing.
Maximum volume of the expansion chamber: the maximum volume of an expansion chamber is the volume of an expansion chamber (which is a working chamber at that phase of an engine cycle when working medium within the working chamber has combusted and is performing work on the rotor) at the last point in the engine cycle before the chamber is exposed to the environment outside of the engine. For example, in the engine 200, the maximum volume of the expansion chamber is the volume of that chamber just before the exhaust passage ceases to be eclipsed, so that there remains, at that last moment, no fluid passage from the exhaust chamber to environment outside of the engine housing.
Angle, or Angle of Rotation.
An engine's rotor is configured so that it may rotate and orbit within the engine. In some embodiments, a rotor orbits the axis of the engine defined by its input/output shaft, driven by the eccentric shaft and with angular velocity of the shaft, while at the same time rotor rotates around its own axis at some angular speed of the shaft and in opposite direction by synchronization means, defined in below. At various positions, the rotor forms various working chambers, and engages intake and exhaust ports, etc. References to the angle of a rotor, or the angle of a rotor's rotation, are references to the position of the rotor within the housing. For example, in
Working medium: the term “working medium” refers to a gas within an engine, and may include, for example, air passing into an intake chamber, air being compressed within a compression chamber, gas within a combustion chamber, and gas within an expansion chamber. A working medium may contain fuel (e.g., gasoline or diesel fuel), or may include the byproducts of combustion.
Eccentricity: the distance between the center of rotation of a shaft, and the geometric center of a circular eccentric fixed to the shaft.
Overview of an Illustrative Embodiment of an Engine
In addition to the housing 201,
Within the engine 200, the rotor is rotatably coupled to an eccentric shaft 210, better seen in
In this embodiment, the rotor 202 has two lobes 202A, 202B, and the aperture 201B has three lobe-receiving regions 220, 221 and 222, as schematically illustrated in
The lobes 202A, 202B are curved and have a curvature. The lobe-receiving regions 220, 221 and 222 are defined by an equal number of intersecting curves, which form an equal number of peaks 205, 206, 207, one peak at each intersection. The curves 209A, 209B, and 209C that define the lobe-receiving regions have a curvature of a similar shape to the curvature of the lobes, so that the inside curve of the lobe-receiving regions 220, 221 and 222 is the same as the outside curve of a lobe 202A, 202B—with the exception that a small gap should exist between the two curves to accommodate manufacturing tolerances and thermal expansion for components—so that any of the lobes may completely occupy any of the lobe-receiving regions, as explained more fully below.
Each peak 205, 206, 207, in turn, has a peak seal 251A, 251B, 251C, and each peak seal is radially biased so as to be in continuous sealing contact with the rotor 202, to form a number of working chambers, as described more fully below.
As the rotor 202 turns inside the aperture 201B, the housing 201 and the rotor 202 cooperate to form three working chambers 250, 252, 253 for executing an engine cycle. More specifically, each working chamber is defined by the circumferential housing 201A, the rotor 202, a number of seals, and the sides 201C, 201D of the housing.
For example, one working chamber 250 is formed by the rotor 202, circumferential housing 201A, and seals 251A and 251B, along with the sides 201C and 201D, and other seals between the rotor and the sides. For ease of illustration, the other seals are not shown in
As illustrated in
Eventually, the lobe 202A completely occupies the lobe-receiving region 221, as schematically illustrated in
This position of the rotor 202 within the lobe-receiving region 221 may be known as “top dead center” or “TDC.” At this point in the engine's cycle, fuel within the combustion chamber ignites, causing heat to be added to the gas, and thereby greatly increasing the pressure of the gas.
Ignition may be initiated in a variety of ways known in the art. However, in this embodiment, the ratio of the initial volume of the compression chamber (V1) and the volume of the combustion chamber (V2) at top dead center may be as high as 30 or more. As such, the fuel and gas mixture within the working chamber may be ignited by compression ignition. Indeed, fuel may be injected into the working chamber before the combustion chamber is closed (e.g., during compression), or at or after the moment that the combustion chamber is closed.
As the rotor 202 continues to rotate, the lobe 202A is substantially stationary for a brief period of time (or over a small angle of rotation) within the lobe-receiving region 221. In other words, while the lobe 202A is at top dead center, the rotation of the shaft 210 effectively causes lobe 202A to pivot within lobe-receiving region 221 before eventually beginning to withdraw from the lobe-receiving region 221 (
Some embodiments have a substantially constant volume for a longer period of time (or greater angle of rotation of a rotor) than could be afforded by rotating rotor. For example, as schematically illustrated in
In various embodiments, the small piston 850 may be spring loaded, or driven externally by cam, electric or hydraulic drives synchronized to the engine cycle. Any such drive mechanism may be known as a “controller.” If driven externally, the piston 850 extends into the combustion chamber 260 and can be controlled so as to maintain a constant volume combustion chamber 260 for a much longer duration. Alternately, the piston 850 may aid in a very rapid compression or in variable compression ratio engines—all of these useful in different modes of operation of the engine, for the purpose of increasing engine efficiency, or enabling the engine to operate on a multitude of fuels. Alternatively, the volume (and the composition) of the gasses during combustion phase could be controlled by water injection.
Returning to
The expanding gas within the expansion chamber 250 exerts force on the rotor 202, thereby causing the rotor 202 to continue its rotation around the eccentric shaft 210, and thereby causing the eccentric shaft 210 to rotate about its axis 210A in a direction counter to the direction of rotation of the rotor 202. In this embodiment, the shaft 210 rotates clockwise, as indicated by the arrow on the eccentric 210B.
As expansion concludes, and the rotor 202 continues to rotate, the exhaust passageway (see
As the rotor 202 continues to rotate, an intake passageway (see
Although the foregoing discussion focuses on working chamber 250,
A number of observations about the engine 200 and its operation may be useful at this point. First, the rotor 202 is in contact with all three of the peak seals 251A, 251B, 251C at all angles of rotation of the rotor 202. Indeed, this is a characteristic of the cycloid rotor that has beneficial consequences as described more fully below.
Also, although the present embodiment has a rotor with two lobes 202A, 202B, and a stationary aperture 201B with three lobe-receiving regions 220, 221, 222, other embodiments may have different numbers of lobes and lobe-receiving regions, with the number of lobe-receiving regions being one more (N+1) than the number of lobes (N) on the corresponding rotor. Also, in other embodiments, both the (N+1)-lobed “housing” and the N-lobed rotor to rotate around another fixed housing, or the N-lobed rotor may be stationary and the (N+1)-lobed “housing” rotates around the rotor.
Housing
More detailed views of embodiments of housings and rotors are provided in
Circumferential Body
The body 201A has three lobe-receiving regions that are intimately related to the rotor 202. For a given rotor coupled to an eccentric with known eccentricity “e,” the geometry of the aperture in a corresponding circumferential body is determined by specifying a set of theoretical rollers 410, 411, 412 disposed on a generating curve 413, as shown in
The geometry of the aperture is then determined by placing the rotor 401 at top dead center of each of the theoretical rollers 410, 411, 412. The opposite end of the rotor 401 then defines the curve 420, 421, 422 of a lobe-receiving region. As a practical matter, consideration must be given to construction of a practical curve of a lobe-receiving region by providing for a gap between the rotor and housing at the rotor receiving regions that will take into account manufacturing tolerances and thermal expansion of components. As this process is repeated for each of the theoretical rollers 420, 421, 422, the geometry of the aperture 430 is defined. The locations of the theoretical rollers correspond to the peaks of the circumferential body. Note that in some embodiments, actual rollers 420, 421, 422 may be fabricated having the dimensions of a “theoretical” roller, and such rotors exist in reality, and not theoretical.
As such, there is a unique relationship between the aperture 430, the rotor 401 and the theoretical rollers 410, 411, 412. As a consequence, the geometry is of the rotor and aperture is completely defined by R and Rr. The radius Rr may be useful in determining the geometry of peak seals or peak rotors, as discussed below.
The cycloid geometry provides a number of beneficial features. For example, the cooperating geometries of the lobe and lobe-receiving region yield a very high compression ratio (i.e., the ratio between the maximum and minimum volumes of a compression chamber, where the minimum volume of the combustion chamber defines a constant combustion chamber volume). In the engine 200, the compression ratio is on the order of between at least 12 to 25, although higher ratios are possible as well. This is an improvement over prior art rotary engines. For example, it is well known that for Wankel engine the practical limit is on the order of about 10, which is not sufficient for compression ignition. That is why there exist no naturally aspirated Wankel diesel engines.
As a practical matter, it is desirable to minimize the gap between the rotor and the housing when rotor located at its “top dead center”, i.e. when geometrically, the working chamber volume is at its smallest.
Covers and Rotor
The intake cover 201C includes apertures that form intake ports 259 to allow air to enter the various working chambers within engine 200. For consideration of symmetry, 3 apertures are chosen in 3-lobe housing configuration, though, different number can be chosen as well.
In this embodiment, rotor 202 includes an intake passage 261 between an intake face 202F of the rotor 202 and the radial face 202R of the rotor 202. In other embodiments, the intake passage may pass through the shaft, while still in others, these two methods could be mixed and matched. For example, some embodiments may have exhaust ports on a cover or side of the housing, as in
The intake passage 261 is intermittently exposed to the intake port 259. Over a range of angles of rotation within the housing, the intake passage 261 will be exposed to a working chamber, creating a temporary intake conduit 262 from the environment outside of the engine 200 into the working chamber. The temporary intake conduit 262 will exist over a range of angular rotations of the rotor 202 within the housing 201, as long as the intake passage 261 is at least partially exposed to the working chamber. At other angular rotations of the rotor 202 within the housing 201, the same intake passage 261 will cyclically align with each of the other working chambers to create a temporary intake conduit to each of these other working chambers.
The exhaust cover 201D includes apertures that form exhaust port 265 to allow spent working medium to exit the various working chambers within engine 200. Similarly to intake cover, for consideration of symmetry, 3 apertures are chosen in 3-lobe housing configuration, though, different number can be chosen as well.
In this embodiment, rotor 202 includes an exhaust passage 270 between an exhaust face 202G of the rotor 202 and the radial face 202R of the rotor 202. In other embodiments, the exhaust passage may pass through the shaft, while still in others, these two methods could be mixed and matched. For example, some embodiments may have intake ports on a cover or side of the housing, as in
In some embodiments, the exhaust passage 270 is intermittently exposed to the exhaust port 265, while in other embodiments the exhaust passage is continuously exposed to the exhaust port 265. Over a range of angles of rotation within the housing, the exhaust passage 270 will align with one of the working chambers, creating a temporary exhaust conduit from the given working chamber to the environment outside of the engine 200. The temporary exhaust conduit will exist over a range of angular rotations of the rotor within the housing, as long as the exhaust passage is at least partially aligned with the working chamber. At other angular rotations of the rotor within the housing, the same passage will cyclically align with each of other working chambers to create a temporary exhaust conduit from each of these other working chambers. The exhaust passage 270 may optionally contain a check valve to prevent back flow of exhaust into the engine during the intake process, while both the exhaust passage and intake passage may be exposed to the working chamber at the same time for a brief period of overlap.
One or both of covers 201C and 201D include a bearing (650,
The motion of the rotor 202 is defined by eccentric shaft 210 and a pair of synchronization gears: a pinion gear 212 fixed to the rotor 202 (the shaft axes passes through this pinion without contacting it), and an internal ring gear 211 fixed to one of the intake cover 201C. The internal ring gear 211 has a 3:2 mesh with the pinion 212.
The shaft 210 has an eccentric 210B with eccentricity e. Some embodiments include a bearing placed between the eccentric part of the shaft 210 and the rotor 202. Other embodiments, such as in
The operation of the intake ports 259, exhaust ports 265, the intake passageway 261 and the exhaust passageway 270 may be further understood with reference to
As the rotor 202 continues to turn, the opening of the intake passageway 261 will eventually pass the peak 206. At that angle of rotation, the opening in the intake passageway 261 will be eclipsed by the peak, so that the intake path or conduit ceases to exist. At that angle, the compression chamber is established, and in fact, at that angle the compression chamber is at its maximum volume (V1).
At the rotor angle shown,
As indicated in the embodiment of
An alternate embodiment 750 is schematically illustrated in
Seal Grid
During operation of an engine, including engine 200 for example, working medium under pressure will seek to escape from the working chambers via any available route. Accordingly, engines contain seals to prevent or at least hinder the escape of working medium from various working chambers. To this end, the seals within an engine may be known as a “sealing grid” or “seal grid.” A sealing grid system for rotary engines is defined as a system of seals sealing flat, axial surfaces of the rotor to flat, axial surfaces of the housing (covers), called side seals or face seals, and radial surfaces of the rotor to radial surfaces of the housing, called peak seals. In some embodiments, the sealing grid may include buttons, which seal between the side seals and the peak seals. A sealing grid system is constructed such that, together with rotor and the housing, the working chamber during compression, combustion and expansion is substantially closed such that high pressure working medium does not leak to adjacent low pressure regions, including intake and exhaust. In practice there will always be a leak path due to manufacturing tolerances as well as a need to leave a gap between the members of the grid themselves or members of the grid and rotor or housing to accommodate thermal expansion of the components; if designed correctly, these leaks could be minimized.
Consider, for example, the Wankel rotary engine—the only commercially successful rotary engine. The engine's geometry was well-known before Wankel. Wankel's contribution was that he developed a theoretical sealing grid, which made this engine technically and commercially feasible.
One embodiment of a sealing grid is schematically illustrated in
With the exception of face seals, all other members of the sealing grid (e.g., peak seals and button seals) are stationary. This is a great advantage over Wankel, in which seals (e.g., apex seals on the rotor travel with the rotor; see
While face seals are traveling with the rotor, they are also being constantly supplied with oil through dedicated oil ports within the covers and since seals are never exposed to intake nor exhaust ports, the oil leakage from these seals is minimized if not eliminated completely. The face seal themselves could have one or more small grooves, channels, or cross hatch that can hold oil, such oil supplied from oil ports located within the covers next to button seals. The shape of the face seals is generated by equation for cycloidal curve in such a way that the neutral plane of the seal always passes through three (for 3-lobe housing) points in the cover, regardless of rotor angular position. Any one or all of these points determine the location of oil ports. Thus, the face seals will be continuously exposed to the oiling ports, while oiling ports are only exposed to the face seals, so that no oil leakage will occur. Furthermore, the face seal is always adjacent to virtual rollers corresponding to optional button seals. This enables optional button seals, occupying the space of the virtual button roller, to be placed between the face seal and the roller/seal. The button seal, as stated above, is stationary and rides on the flat surface, or landing, of the rotor, closing gap between face seal and the peak seal.
Face Seals
In the embodiment of
Each of the face seals described herein may be of a cast iron material. However, other suitable materials for use as a face seal include, for example, steel alloys and other alloys. Generally, a face seal, and the material from which it is made, should have sufficient strength to perform under the demanding environments of an internal combustion engine as described herein, and also have low friction, low wear, and a low coefficient of thermal expansion. A face seal should also have some capacity to hold lubricant (e.g., oil), and should have high thermal conductivity.
While
An embodiment of a face seal 1001 is schematically illustrated in
An illustrative embodiment of one such band 1101A is schematically illustrated in
An alternate embodiment of a segmented band 1150 is schematically illustrated in
Alternate embodiments of face seals are schematically illustrated in
The seal above may have an axial (flat) surface 1210 in
If the chamfered surface 1201B of the face seal 1201 has the same chamfer angle as the wedge seal 1220 the small part of the face seal could be designed to move together with the wedge seal 1220, thus reducing or totally eliminating the gap between face seal 1201 and wedge seal 1220.
A post 1230 is disposed in the rotor 1202 adjacent to the face seal 1201 and serves to prevent the face seal 1201 from riding up the beveled edge 1203 and over the axial face 1202F of rotor 1202. A wedge seal 1220 is disposed on the other side of face seal 1201, opposite the post 1230, and serves to prevent the face seal 1201 from moving away from the rotor 1202.
An alternate structure for holding a face seal 1250 to the rotor 1202 is schematically illustrated in
Still another approach to holding a face seal 1260 to the rotor 1202 is schematically illustrated in
Yet another alternate structure for holding a face seal 1270 to the rotor 1202 is schematically illustrated in
Alternate approaches to face seals are schematically illustrated in
Any high-temperature steel or tungsten wire could be used for the wire seal 1301. The leakage path for cold start conditions is calculated at 0.11 mm2 in cross-section for a 0.020″ wire diameter; for hot operating conditions—the cross-section is at 0.03 mm2. There exists four places for the leakage path—2 sides of the rotor×2 places by the apex seals; therefore total leakage path for this type of side seals is 0.33 mm2 for cold start and 0.12 mm2 for hot operating conditions. This is to be compared with ˜4 mm2 leakage area for Wankel engines [see Performance and Combustion Characteristics of Dire-Injection Stratified-Charge Rotary Engines, Nguyen, Hung Lee, N.A.S.A. 1987).
In another embodiment, illustrated in
In another embodiment, illustrated in
An alternate embodiment is schematically illustrated in
An alternate embodiment is schematically illustrated in
To facilitate a seal, an oil film is provided to fill the aforementioned gap. Due to the capillary forces the oil will fill the gap completely and will resist the pressure from the working medium (e.g., gases) within the engine. In addition, the oil film will drastically decrease the friction between the seal and the cover, and thereby enhance the cooling of the engine.
As mentioned above, one beneficial feature of the cycloidal-rotor geometry of engine 200 is that, for at least in three points on the cover, lubrication ports (holes) may be disposed such that they will be always above the face seal. Also, the intake/exhaust ports on the covers are placed in such a way that side seals never interfere with these ports. As such, this geometry enables the creation of a permanent oil layer on the top of the face seals. To enhance this layer the top surface of the face seal can have oil grooves and/or pads of various designs to create elastohydrodynamic lubricating conditions required to decrease the friction between a face seal and an adjacent cover.
Rollers
As described above in connection with other embodiments, each peak 1505 in the circumferential body 1501 of a housing 1502 has a peak seal, but alternate embodiments, schematically illustrated in
In the embodiment of
Alternate embodiments of a seal grid are schematically illustrated in
Peak Seals
A variety of peak seals are available for use in various engine embodiments. As shown in
To this end, each peak seal may include a spring that engages the peak seal channel 825, resulting in a radial force on the peak seal in the direction of the rotor 202. Two such embodiments are schematically illustrated in
Another embodiment of a peak seal 1901 is schematically illustrated in
The edges of the peak seals 1902,1903, where the peak seal meets the rotor, are preferably curved, as schematically illustrated in
Yet other embodiments of peak seal 2001, 2010, and 2020 are schematically illustrated in
It should be noted, that unlike Wankel apex seals, which require approximately 0.070-0.110 inches of travel for the seals on its rotor (for approximately 100 kW engine), no peak seal in the various embodiments described above travel more than 0.01 inches (0.0254 centimeters) at the most and, in some embodiments, possibly a lot less.
Button Seals
A simple button seal 810 is schematically illustrated in
To that end, the button 810 in
Although embodiments above have been described in the context of a cycloidal rotor, many of the features may be used in a variety of engines.
For example, a rotary engine compartment 2100 having a three-lobed rotor 2102 is schematically illustrated in
In the embodiment of
The inner rotor 2102 rotates and drives the outer rotor. Spring-loaded or oil supported rollers 2110 aid in sealing and reduce friction. Intake ports and exhaust ports are shaped and located in such a way that intake volume is less than expansion volume. A substantially constant volume combustion chamber is possible due to relatively slow rate of volume expansion that exists right after the combustion.
During operation of this embodiment, variable volume cavities, or working chambers, are created by inner and outer rotors and housing covers. Each chamber rotates and in a course of its motion changes the volume from minimal, V2, corresponding to constant volume combustion chamber volume, to a maximum, V4, corresponding to an exhaust volume. Fuel is injected through stationary fuel injectors (not shown) located within covers. The operation is typically according to a HEHC-S cycle where air is scavenged (exhausted and induced), air is compressed, fuel is injected and combusted, and the combustion products are expanded. While a ¾ configuration is shown ⅔, ⅘, etc. configurations are equally possible. This engine may also be operated in a digital mode.
Another embodiment includes a single vane configuration. An engine assembly with such a rotor is schematically illustrated in
The housing 2201 of this embodiment together with the vane 2202, forms 4 (in this instance) variable volume cavities, or chambers, which are analogous to a 4-cylinder piston engine. Vanes 2202 engaging each chamber, in turn, simulate a 4-stroke operation. The working medium will be induced, compressed, combusted, expanded, and exhausted.
The housing will house a constant volume combustion chamber which may be located in housing proper, or in the cover. Conventional poppet valves or spherical valves or disk valve may be used to control timing of intake and exhaust stroke. The valves are not shown in this figure. If constant volume combustion chamber 2220 is located within housing as shown, then cylindrical valves may be employed. These valves would be concentric with the combustion chamber and would rotate exposing the opening from the constant volume combustion chamber to intake or exhaust ports. Having intake valves open while chamber volume is being decreased allows a smaller intake volume than exhaust volume, thus achieving an Atkinson part of the cycle. This embodiment may also be operated in a digital mode of operation and may be used with a fuel injection system.
An alternate embodiment of an engine 2301 with a three-lobed rotor 2300 is schematically illustrated in
Such an engine has a housing having a working cavity, a shaft with an eccentric portion, a rotor disposed on the eccentric portion and within the working cavity, a hub comprising plurality of rotors, a plate fixedly coupled to the shaft, the plate having several apertures, such that each of rollers passes through a corresponding one of the plurality of apertures. In operation, the rotation of the rotor causes the rollers to circulate around the apertures, such that the eccentric motion of the rotor is transferred to circular motion in the plate.
It should be noted that feature of the embodiments of
Another embodiment 2901 is schematically illustrated in
An alternate embodiment of an engine is schematically illustrated in
An alternate configuration for gas exchange (intake and exhaust) is also shown in
The various embodiments described above may be operated at a partial load, using conventional fuel modulation or fuel skip-cycle methods as described below. For example, to operate at part load, especially with heavy fuels like Diesel, JP8, etc., a number of options are available. For example, the amount of fuel provided to the engine may be modulated as in as in conventional engines.
Alternatively, the engine may be run in “digital mode”—by running every firing cycle at full load, but skipping a percentage of cycles. For example, skipping three out of each ten cycles would enable the engine to run under 70% of full power; skipping eight out of each ten cycles will enable the engine to run under 20% load, etc. The cycle skipping can be implemented simply by cutting off the fuel supply. In this case, the air compressed in a compression chamber will expand in an expansion chamber, even though no combustion occurred in the interim. This will not only occur with minimal loss in energy, as working medium (air, in this case) acts as an air spring, but some energy recovery is possible, as heat is transferred from the working chamber's walls to the air, thereby cooling the engine internally, while increasing the temperature and, therefore, pressure of the expanding gases, thereby some of the losses affiliated with cooling the engine may be partially recovered as useful work.
In analogy with conventional piston engines the HEHC may be called 4-stroke cycles as they have 4 distinctive strokes: Intake, Compression, Combustion & Expansion, and Exhaust. A scavenging variant of the HEHC (HEHC-s) is equivalent to a 2-stroke engine cycle wherein, at the end of expansion, the cavity is scavenged by the blow-by ambient air, which removes combusted gasses and refills the cavity with a fresh air or an air/fuel mixture charge.
A HEHC pressure-volume diagram is shown in FIGS. 1 and 2 of U.S. published patent application US 20110023814 A1. In the initial state, only the air is compressed, like in Diesel cycle, during the compression stroke. Fuel may be added close to the end of compression stroke or just after the compression stroke. Since air is already compressed at this point to a relatively high pressure (˜55 bar), high injection pressures, similar to those used in modern diesel engines are required to achieve full combustion and clean exhausts. The operation is akin to Diesel engines except for the fact that combustion occurs at the constant volume, as achieved in Otto cycle engines that are spark ignited. However, unlike spark ignition engines, the combustion occurs due to fuel injection into a very hot compressed air. Having said this, however, a spark plug may be used as well. Expansion occurs in this cycle to ambient pressures, similar to Atkinson cycle.
Partial load operation may be accomplished by fuel modulation, as in Diesel engines or by skipping some of the injections all together, as it will be described below.
Due to similarities of this cycle to Diesel, Otto and Atkinson, this cycle is referred to as a “Hybrid Cycle”. It may also possible to inject water during combustion and/or expansion strokes as this may improve the efficiency of the engine, while providing for cooling from within the engine.
If leakage between moving components and housing is kept at low level, the maximum efficiency of this cycle is expected to be about 57%, while average efficiency is expected to be above 50%.
The embodiment 3201 schematically illustrated in
The cycle begins with the start of the fresh air intake stroke, at which point the rotor 3202 is within lobe-receiving region 3210, as schematically illustrated in
As the rotor 3202 continues to turn, it eventually completely occupies the lobe-receiving region 3210, and the working medium is confined within a combustion chamber 3251, as schematically illustrated in
The combustion increases the pressure of the working medium, which in turn exerts force on the rotor 3202, causing the rotor 3202 to continue its rotation, and thereby allowing the working medium to expand in an expansion phase of the HEHC cycle, as schematically illustrated in
Finally, the expansion phase ends, and the working medium is exhausted to the environment outside of the engine 3201, as schematically illustrated in
Although the embodiments above have been described in terms of internal combustion engines, some embodiments may be used as an expander, such as in a steam engine, for example. Indeed, various embodiments may be configured as an external heat engine (e.g., an external combustion engine). For example, heat may be supplied into a working chamber by placing a heat pipe into the volume described above as a combustion chamber, to allow transfer of external heat from solar, combustion, nuclear, etc. into that chamber.
Indeed, the disclosure herein will support a broad variety of potential claims. For example, in embodiments with a wedge seal, and/or with a face seal on a chamfered edge of a rotor, pressure (such as gas pressure for example) will generate a radial force on the face seal, and that force will, in turn, bias the face seal to ride up the chamfered edge, thereby converting the force into axial movement of the seal by the chamfered edge of the rotor. Also, in some embodiments, a face seal may have an axial (flat) surface that could be a very short distance away from the surface of the cover. This creates a gap for gas to pass through and create pressure/force in opposite direction to the above mentioned axial force. The surface area of this gap controls the axial force—that often serves as an unwanted brake, thereby reducing friction between face seal and the cover.
If a surface of the peak seal has the same chamfer angle as the wedge seal—the small part of the peak seal could be designed to move together with the wedge seal, thus reducing or totally eliminating the gap between peak and wedge seal.
A variety of seals, such as face seals and peak, are described above, and or all of which could be claimed, either alone, or in the context of a seal grid.
In addition, embodiment of engines described herein may be operated in a variety of modes. For example, embodiments may be operated in a 2-stroke mode, or a variety of 4-stroke modes, including without limitation, executing an HEHC cycle (i.e., HEHC operation).
Some other potential claims are listed below.
P1. A rotary engine comprising:
a housing having a working cavity;
a shaft having an eccentric rotor integral with, or fixedly attached to, the shaft, the eccentric rotor disposed within the working cavity;
at least one hydrodynamic bearing supporting the shaft, so as to allow the eccentric rotor to rotate within the working cavity.
P2. A rotary engine comprising:
a housing having a working cavity;
a shaft, the shaft having an eccentric portion;
a rotor disposed on the eccentric portion and within the working cavity;
a hub comprising plurality of rotors;
a plate fixedly coupled to the shaft, the plate comprising a plurality of apertures, each of the plurality of rollers passing through a corresponding one of the plurality of apertures,
wherein the rotation of the rotor causes the rollers to circulate around the apertures, such that the eccentric motion of the rotor is transferred to circular motion in the plate.
P3. A rotary engine comprising:
a housing having a working cavity;
a sealing grid;
a rotor shaft having a rotor integral with, or fixedly attached to, the shaft, the rotor disposed within the working cavity; and
at least one input/output shaft disposed in the engine to as to eccentrically support the rotor shaft.
P4. The engine of potential claim P3, wherein the input/output shaft is configured to serve as a counterweight to dynamically balance the rotor.
P5. The engine of potential claim P3, the rotor shaft and the intake/output shaft further comprising intake and exhaust passages (e.g., A rotary engine having a gas exchange system comprising the intake and exhaust port and passages through the intake/output shaft and the rotor).
P6. The engine of potential claim P3, further comprising a hydrodynamic bearing supporting input/output shafts.
The embodiments of the invention described above are intended to be merely exemplary; numerous variations and modifications will be apparent to those skilled in the art. All such variations and modifications are intended to be within the scope of the present invention as defined in any appended claims. For example, any the various seals disclosed above may be used with any of the various rotors described herein. Similarly, any of the various intake and exhaust ports may be used with any of the rotors and/or shafts described herein.
This patent application is a continuation application of U.S. patent application Ser. No. 14/015,848 filed Aug. 30, 2013, now U.S. Pat. No. 9,535,623, which is a continuation application of U.S. patent application Ser. No. 13/551,032 filed Jul. 17, 2012, now U.S. Pat. No. 8,523,546, which is a continuation application of U.S. patent application Ser. No. 13/434,827 filed Mar. 29, 2012, which claims priority from U.S. Provisional Patent Application No. 61/469,009, filed Mar. 29, 2011, the disclosures of which are incorporated herein by reference in their entirety.
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Number | Date | Country | |
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Parent | 14015848 | Aug 2013 | US |
Child | 15160094 | US | |
Parent | 13551032 | Jul 2012 | US |
Child | 14015848 | US | |
Parent | 13434827 | Mar 2012 | US |
Child | 13551032 | US |