Patent Description:
Rotary engines, such as for example Wankel engines, use the eccentric rotation of a piston to convert pressure into a rotating motion, instead of using reciprocating pistons. In these engines, the rotor includes a number of apex or seal portions which remain in contact with a peripheral wall of the rotor cavity of the engine throughout the rotational motion of the rotor to create a plurality of rotating cavities when the rotor rotates.

In Wankel engines, the inlet and exhaust ports are usually designed mechanically to allow a minimum overlap between them during the intake and exhaust portions of the cycle, such as to purge the exhaust cavity of combustion gases prior to re-filling the intake cavity with a fresh supply of air. Failure to purge the exhaust cavity of the combustion gases may result in a reduction in cycle volumetric efficiency. However, overlap of the ports may limit the range of volumetric compression ratio that can be obtained. Therefore, there remains a need for improvement in optimizing how rotary engines may be operated.

<CIT> discloses an intake device for a rotary engine.

<CIT> discloses a rotary piston internal combustion engine of the trochoidal type.

<CIT> discloses a rotary piston internal combustion engine.

<CIT> discloses a compound cycle rotary engine.

In one aspect, there is provided a compound engine system as recited in claim <NUM>.

In a further aspect, there is provided a method of operating a compound engine system as recited in claim <NUM>.

Referring to <FIG>, a rotary internal combustion engine <NUM> known as a Wankel engine is schematically shown. In a particular embodiment, the rotary engine <NUM> is used in a compound cycle engine system such as described in <CIT> or as described in<CIT>. The compound cycle engine system may be used as a prime mover engine, such as on an aircraft or other vehicle, or in any other suitable application. In any event, in such a system, air is compressed by a compressor before entering the Wankel engine, and the engine drives one or more turbine(s) of the compound engine. In another embodiment, the rotary engine <NUM> is used without a turbocharger.

The engine <NUM> comprises an outer body <NUM> having axially-spaced end walls <NUM> with a peripheral wall <NUM> extending therebetween to form a rotor cavity <NUM>. The inner surface of the peripheral wall <NUM> of the cavity <NUM> has a profile defining two lobes, which is preferably an epitrochoid.

An inner body or rotor <NUM> is received within the cavity <NUM>. The rotor <NUM> has axially spaced end faces <NUM> adjacent to the outer body end walls <NUM>, and a peripheral face <NUM> extending therebetween. The peripheral face <NUM> defines three circumferentially-spaced apex portions <NUM>, and a generally triangular profile with outwardly arched sides. The apex portions <NUM> are in sealing engagement with the inner surface of peripheral wall <NUM> to form three rotating working chambers <NUM> between the inner rotor <NUM> and outer body <NUM>. The geometrical axis of the rotor <NUM> is offset from and parallel to the axis of the outer body <NUM>.

The working chambers <NUM> are sealed, which may typically improve efficiency. Each rotor apex portion <NUM> has an apex seal <NUM> extending from one end face <NUM> to the other and protruding radially from the peripheral face <NUM>. Each apex seal <NUM> is biased radially outwardly against the peripheral wall <NUM> through a respective spring. An end seal <NUM> engages each end of each apex seal <NUM>, and is biased against the respective end wall <NUM> through a suitable spring. Each end face <NUM> of the rotor <NUM> has at least one arc-shaped face seal <NUM> running from each apex portion <NUM> to each adjacent apex portion <NUM>, adjacent to but inwardly of the rotor periphery throughout its length. A spring urges each face seal <NUM> axially outwardly so that the face seal <NUM> projects axially away from the adjacent rotor end face <NUM> into sealing engagement with the adjacent end wall <NUM> of the cavity. Each face seal <NUM> is in sealing engagement with the end seal <NUM> adjacent each end thereof.

Although not shown in the Figures, but as well understood, the rotor is journaled on an eccentric portion of a shaft and includes a phasing gear co-axial with the rotor axis, which is meshed with a fixed stator phasing gear secured to the outer body co-axially with the shaft. The shaft rotates the rotor and the meshed gears guide the rotor to perform orbital revolutions within the stator cavity. The shaft performs three rotations for each orbital revolution of the rotor. Oil seals are provided around the phasing gear to prevent leakage flow of lubricating oil radially outwardly thereof between the respective rotor end face <NUM> and outer body end wall <NUM>.

During one orbital revolution, each chamber varies in volumes and moves around the stator cavity to undergo the four phases of intake, compression, expansion and exhaust, these phases being similar to the strokes in a reciprocating-type internal combustion engine having a four-stroke cycle.

The engine includes a primary inlet port <NUM> defined through one of the walls of the stator body <NUM>. In the embodiment shown, the primary inlet port <NUM> is a side port defined in one of the end walls <NUM>. Another opposed primary inlet port may be similarly defined in the other end wall. The primary inlet port <NUM> is in communication with an air source through an intake duct <NUM> which is defined as a channel in the end wall <NUM>. The air has a pressure slightly greater than the exhaust pressure of the engine. In a particular embodiment the air source is the air output of the compressor of a compound engine, though any suitable source may be used. The primary inlet port <NUM> delivers air to each of the chambers <NUM>, and a fuel injection port (not shown) is also provided for delivering fuel into each chamber <NUM> after the air therein has been compressed. Fuel, such as kerosene (jet fuel) or other suitable fuel, is delivered into the chamber <NUM> such that the chamber <NUM> is stratified with a rich fuel-air mixture near the ignition source and a leaner mixture elsewhere, thus providing a so-called stratified charge arrangement, and the fuel-air mixture may be ignited within the housing using any suitable ignition system known in the art. In another embodiment, fuel and air can be mixed outside the engine and delivered as a premixed charge through the primary inlet port <NUM>.

The engine also includes an exhaust port <NUM> defined through one of the walls of the stator body <NUM>. In the embodiment shown, the exhaust port <NUM> is a peripheral port defined as an opening through the peripheral wall <NUM>. The rotary engine <NUM> operates under the principle of the Atkinson or Miller cycle, with its compression ratio lower than its expansion ratio. For example, the ratio obtained by dividing the volumetric compression ratio by the volumetric expansion ratio may be between <NUM> and <NUM>. Accordingly, the primary inlet port <NUM> is located further away (i.e. measured as a function of piston rotation) from the exhaust port <NUM> when compared to an engine having compression and expansion ratios that are equal or approximately equal to one another. The angle of the primary inlet port <NUM>, relative to the angle of the exhaust port <NUM>, can then be determined to achieve a desired peak cycle pressure given the inlet air pressure. The position of the primary inlet port <NUM> may vary between the <NUM> o'clock position up to the <NUM> o'clock position. In the embodiment shown, the primary inlet port <NUM> extends between the <NUM> o'clock and the <NUM> o'clock positions.

Because of the Miller cycle implementation, the primary inlet port <NUM> is positioned relative to the exhaust port such that the compression ratio is significantly lower than the expansion ratio. In the embodiment shown, the primary inlet port <NUM> is spaced from the exhaust port <NUM> so that the rotor <NUM> at least substantially prevents communication therebetween in all rotor positions. In other words, each revolution of the rotor <NUM> can be said to include, for each of the chambers <NUM>, an exhaust portion where the chamber <NUM> directly communicates with or contains the exhaust port <NUM>, and an intake portion where the chamber <NUM> directly communicates with or contains the inlet port <NUM>, and the exhaust and intake portions of the revolution for a same chamber do not overlap.

The engine <NUM> also includes a secondary inlet port or purge port <NUM> defined through one of the walls of the stator body <NUM>, and communicating with an air source, which may be the same source communicating with the primary inlet port <NUM>. In the embodiment shown, the purge port <NUM> is a side port defined in one of the end walls <NUM> and communicates with the air source through the same intake duct <NUM> as the primary inlet port <NUM>. The purge port <NUM> is located rearwardly of the primary inlet port <NUM> and forwardly of the exhaust port <NUM> relative to the direction R of the rotor revolution and rotation. The purge port <NUM> is located such as to be in communication with the exhaust port <NUM> through each of the chambers <NUM> along a respective portion of each revolution. In other words, each revolution of the rotor <NUM> can be said to include, for each chamber <NUM>, a purge portion, which is a final stage of the exhaust portion, where the chamber <NUM> directly communicates with or contains both the purge port <NUM> and the exhaust port <NUM>. In the embodiment shown, the purge port <NUM> is also located such as to be in communication with the primary inlet port <NUM> through each of the chambers <NUM> along a respective portion of each revolution. Alternately, the purge port <NUM> may be spaced from the primary inlet port <NUM> so that the rotor <NUM> at least substantially prevents communication therebetween in all rotor positions.

The purge port <NUM> may thus allow for smaller volumetric compression ratios to be achieved while still achieving adequate purging of the exhaust cavity.

Although not shown, the inlet ports <NUM>, <NUM> may be connected to Helmholtz resonators for which may enhance volumetric efficiency and/or minimize the pumping loss during the intake phase.

In an alternate arrangement outside the scope of the claims, the primary inlet port <NUM> is also located such as to be in communication with the exhaust port <NUM> through each of the chambers <NUM> along a respective portion of each revolution.

In use, through each orbital revolution of the rotor, each chamber <NUM> is filled with air (pressurized air from a compressor for example) through the primary inlet port <NUM> during the respective intake portion of the revolution, i.e. the portion of the revolution where the chamber <NUM> directly communicates with the primary inlet port <NUM>. The air is then further compressed by the reducing volume of the rotating chamber <NUM>. Once the air is further compressed, near minimum volume of the chamber <NUM>, the air is mixed with fuel and the resulting air-fuel mixture is ignited. The combustion gases expand and force the volume of the chamber <NUM> to increase. As mentioned above, the primary inlet port <NUM> is positioned relative to the exhaust port <NUM> such that the volumetric expansion ratio is higher than the volumetric compression ratio. The combustion or exhaust gases exit the chamber <NUM> through the exhaust port <NUM> during the exhaust portion of the revolution, i.e. the portion of the revolution where the chamber <NUM> communicates with the exhaust port <NUM>. The last part of the exhaust portion defines the purge portion of the revolution, where the chamber <NUM> is in communication with both the purge port <NUM> and the exhaust port <NUM>, and the air entering the chamber <NUM> through the purge port <NUM> is used to purge remaining exhaust gases from the chamber <NUM>.

In a particular embodiment, the communication of the chamber <NUM> with the exhaust port <NUM> is closed prior to re-filling the chamber <NUM> with air through the inlet port <NUM>, i.e. the inlet port <NUM> does not participate in the purge of the exhaust gases. In an alternate embodiment, the exhaust port <NUM> is still open when the inlet port <NUM> starts to open.

Referring to <FIG>, an engine <NUM> according to another embodiment is shown, with similar elements being indicated by the same reference numerals employed in the description above. In this embodiment, the primary inlet port <NUM> is defined through the end wall <NUM> between the <NUM> o'clock and the <NUM> o'clock positions, and communicates with the air source by an intake duct <NUM> which is independent from the purge port <NUM>. The secondary inlet port or purge port <NUM> is defined by an exit port of a purge line <NUM> extending through the peripheral wall <NUM> and having an entry port <NUM> opening into the cavity <NUM> adjacent the primary inlet port <NUM>. As such, the air enters the adjacent chamber in communication with the primary inlet port <NUM>, and circulates to the chamber being purged through the purge line <NUM> and the purge port <NUM>. The purge port <NUM> is located such as to be in communication with the exhaust port <NUM> through each of the chambers <NUM> along a respective portion of each revolution, to purge the exhaust gases from the chamber <NUM>.

The engine <NUM> also operates under the principle of the Atkinson or Miller cycle, with its compression ratio lower than its expansion ratio. In the embodiment shown, the rotor <NUM> at least substantially prevents direct communication between the primary inlet port <NUM> and the exhaust port <NUM> in any rotor position, with communication being provided through the purge line <NUM>. Alternately, in an arrangement falling outside the scope of the claims, the rotor <NUM> may allow the primary inlet port <NUM> and exhaust port <NUM> to be in momentary direct communication with each other through each chamber <NUM> sufficiently to purge burnt exhaust gases prior to ingestion of a fresh charge of air for the next combustion cycle.

Referring to <FIG>, an engine <NUM> according to another embodiment is shown, again with similar elements being indicated by the same reference numerals. Like in the previous embodiment, the primary inlet port <NUM> is defined through the end wall <NUM> and communicates with the air source through an intake duct <NUM>. The exhaust port <NUM> is a side port, defined in one or both of the end walls <NUM>, and is in communication with the environment of the engine <NUM> through an exhaust duct <NUM> which is defined as a channel in the end wall <NUM>.

The purge port <NUM> is a peripheral port, defined as an opening through the peripheral wall <NUM>. The purge port <NUM> and exhaust port <NUM> communicate through each of the chambers <NUM> along a respective portion of each revolution to purge the exhaust gases. The purge port <NUM> is connected to the air source, which may be air bled from the adjacent cavity in communication with the primary inlet port <NUM> or the air source to which the primary inlet port <NUM> is connected, through a valve <NUM> (only schematically shown), such as to modulate the purge flow as a function of engine operation conditions, allowing selective recirculation of some of the exhaust gases, for example to optimize the power output, minimize the emission levels, or for another purpose, as will be further detailed below. Although not shown, a similar valve may connect the primary inlet port <NUM> to the air source.

The engine <NUM> also operates under the principle of the Atkinson or Miller cycle, with its compression ratio lower than its expansion ratio. In the embodiment shown, the rotor <NUM> prevents direct communication between the primary inlet port <NUM> and the exhaust port <NUM> in any rotor position. Alternately, in an arrangement outside the scope of the claims the rotor <NUM> may allow the primary inlet port <NUM> and exhaust port <NUM> to be in momentary direct communication with each other through each chamber <NUM>.

Referring to <FIG>, an engine <NUM> according to yet another embodiment is shown. The engine <NUM> is similar to the engine <NUM>, with a similar purge port <NUM> and corresponding valve <NUM> (and optional valve, not shown, on the inlet port <NUM>), but the position of the exhaust port <NUM> differs. In this embodiment, the rotor <NUM> prevents direct communication between the secondary inlet port or purge port <NUM> and the exhaust port <NUM> in all rotor positions. A secondary exhaust port <NUM> is provided in the form of a peripheral port defined as an opening through the peripheral wall <NUM>. The secondary exhaust port <NUM> is located forwardly of the primary exhaust port <NUM> and rearwardly of the purge port <NUM> along the direction of revolution R, in proximity to the primary exhaust port <NUM>. The purge port <NUM> and secondary exhaust port <NUM> communicate through each of the chambers <NUM> along a respective portion of each revolution to purge the exhaust gases, after communication of the chamber <NUM> with the primary exhaust port <NUM> has been blocked, to purge the chamber <NUM>.

The engine <NUM> also operates under the principle of the Atkinson or Miller cycle, with its compression ratio lower than its expansion ratio. In the embodiment shown, the rotor <NUM> prevents direct communication between the primary inlet port <NUM> and the exhaust ports <NUM>, <NUM> in all rotor positions.

Referring to <FIG>, an engine <NUM> according to a further embodiment is shown. The engine <NUM> has a primary inlet port <NUM> located between the <NUM> o'clock and <NUM> o'clock positions, and a secondary inlet port or purge port <NUM>, with both inlet ports <NUM>, <NUM> being defined in the form of peripheral ports as openings through the peripheral wall <NUM>. The primary inlet port <NUM> and secondary inlet port <NUM> are each connected to a same connecting duct <NUM>, which can be for example a plenum, a Y-piece, etc., through a respective conduit <NUM>, <NUM>. Each conduit includes a valve <NUM>, <NUM> therein that can selectively open or close it. The connecting duct <NUM> communicates with the air source, for example the exhaust of a compressor in the case of a compound cycle engine system, through an intake duct <NUM>. The exhaust port <NUM> is a peripheral port similar to that of the embodiments of <FIG>.

The rotor <NUM> prevents direct communication between the primary inlet port <NUM> and the exhaust port <NUM> in any rotor position. Alternately, in an arrangement falling outside the scope of the claims, the rotor <NUM> may allow the primary inlet port <NUM> and exhaust port <NUM> to be in momentary direct communication with each other through each chamber <NUM>.

The valves <NUM>, <NUM> which can be for example pneumatic, electric or hydraulic valves, are controlled, either passively or electronically, to modulate the flow between the primary and secondary inlet ports <NUM>, <NUM>, to vary the pressure ratios of the engine to optimize the engine operation at off-design conditions. Such modulation may allow for a suitable trade-off between mission fuel burn, engine power and exhaust gas atmospheric emissions or other factors.

In a particular embodiment, the valves <NUM>, <NUM> are controlled as follows during three different stages of operation of the engine.

In use, in one example such as during a first operational stage, which corresponds to engine start-up, the primary valve <NUM> is closed or substantially closed, and the secondary valve <NUM> is open, so that only (or primarily) the secondary inlet port <NUM> delivers air to the chambers <NUM>. Doing so may allow for a relatively higher volumetric compression ratio than would otherwise be available, which increases the air temperature and facilitates combustion, which it turn may facilitate start-up, and perhaps especially during cold starts. The secondary inlet port <NUM> may be positioned such that the engine in this configuration has a volumetric compression ratio which is near, e.g. equal or substantially equal, to the volumetric expansion ratio of the engine.

In another example, during a second operational stage of the engine, which corresponds to engine idle or low power operation, the secondary valve <NUM> is closed or substantially closed, either abruptly or progressively, and the primary valve <NUM> is open. With the secondary valve <NUM> closed, purging of the exhaust gases is significantly reduced/impeded (if the primary inlet port <NUM> and exhaust port <NUM> communicate, which falls outside the scope of the claims) or prevented (if the rotor <NUM> prevents communication between the primary inlet port <NUM> and exhaust port <NUM>), which reduces exhaust and thus may help minimize the emission levels of the engine when in this condition. The primary inlet port <NUM> is positioned such that the engine in this configuration operates under the principle of the Atkinson or Miller cycle, with its compression ratio lower than its expansion ratio.

In another example, during a third operational stage of the engine, which corresponds to high power operation of the engine, both valves <NUM>, <NUM> are open, so that the secondary inlet port <NUM> acts as a purge port as discussed above. The secondary valve <NUM> may be opened, partially or completely, as the power demand increases. The relatively lower volumetric compression ratio of the Atkinson or Miller cycle (as compared to standard cycles) combined with the purging of the exhaust gases from the cavities help maximize power output. In a particular embodiment, the third operational stage may start at approximately <NUM>-<NUM>% of maximum power of the engine. However this point can be varied by an electronic control (not shown) sending a signal to the valve actuator to vary the opening of the valve such that the desired outputs (power, emissions, fuel consumption and exhaust gas temperature) are optimized for different operating conditions such as ambient temperature, altitude, throttle levels and rotor speeds.

Similar valves and controls may be provided with other embodiments, for example the embodiments shown in <FIG>. Air to the inlet ports may be controlled in other engine operational stages, or scenarios, to provide specific benefits or operational effects, as desired.

Claim 1:
A compound engine system having a compressor, a turbine and a rotary engine (<NUM>; <NUM>; <NUM>; <NUM>; <NUM>), the engine having a stator body (<NUM>) having walls defining an internal cavity (<NUM>), and a rotor body (<NUM>) mounted for eccentric revolutions within the cavity (<NUM>), the rotor and stator bodies cooperating to provide rotating chambers (<NUM>) of variable volume when the rotor moves relative to the stator, the engine comprising at least an inlet port (<NUM>; <NUM>; <NUM>; <NUM>; <NUM>), an exhaust port (<NUM>; <NUM>; <NUM>; <NUM>) and a purge port (<NUM>; <NUM>; <NUM>; <NUM>) defined in the stator body (<NUM>) and communicating with the cavity (<NUM>), the inlet port (<NUM>; <NUM>; <NUM>; <NUM>; <NUM>) and purge port (<NUM>; <NUM>; <NUM>; <NUM>) being in communication with an air source, the purge port (<NUM>; <NUM>; <NUM>; <NUM>) being located rearwardly of the inlet port (<NUM>; <NUM>; <NUM>; <NUM>; <NUM>) and forwardly of the exhaust port (<NUM>; <NUM>; <NUM>; <NUM>) relative to a direction of the rotor revolution (R), the purge port (<NUM>; <NUM>; <NUM>; <NUM>) momentarily communicating with the exhaust port (<NUM>; <NUM>; <NUM>; <NUM>) through each of the chambers (<NUM>) when the rotor is positioned in a respective portion of the rotor revolution, wherein
the rotor (<NUM>) is configured and ports are located to prevent direct communication between the inlet port (<NUM>; <NUM>; <NUM>; <NUM>; <NUM>) and the exhaust port (<NUM>; <NUM>; <NUM>; <NUM>) through the rotating chambers (<NUM>) in any rotor position; and wherein
the inlet and outlet ports are located relative to one another such that a volumetric compression ratio of the engine is lower than a volumetric expansion ratio of the engine, wherein the inlet port (<NUM>; <NUM>; <NUM>; <NUM>; <NUM>) and purge port (<NUM>; <NUM>; <NUM>; <NUM>) communicate with the compressor and the exhaust port (<NUM>; <NUM>; <NUM>; <NUM>) communicates with the turbine.