The present application relates to rotary vane engines that produce torque as a result of the expansion of gases therein, and engine systems that incorporate rotary vane engines.
Engine systems that include rotary vane engines (hereinafter referred to as “rotary vane engine systems”) possess various advantages in relation to engines such as Otto, diesel, and Sterling-cycle engines, gas turbines, and steam engines.
For example, Otto-cycle engines require a minimum fuel to air ratio to achieve combustion. The minimum fuel to air ratio at which combustion can be achieved typically results in incomplete combustion. Incomplete combustion produces relatively large amounts of carbon monoxide (CO) in the exhaust, and can necessitate the use of a catalytic converter to remove some or all of the CO form the exhaust. Rotary vane engine systems, by contrast, can operate with a combustion process that provides complete combustion with excess oxygen present in the exhaust, without the use of catalytic converters or other pollution-control devices.
Moreover, the fuel used in an Otto-cycle engine needs to be formulated so that the fuel will not combust prematurely, i.e., at a pressure or temperature lower than the operating respective pressure and temperature of the engine. Premature combustion is commonly known as “pre-ignition knock.” Pre-ignition knock can substantially reduce engine efficiency, and can damage the engine. Rotary vane engine systems are not susceptible to pre-ignition knock, and can generally use any type of fuel that releases sufficient energy during combustion to drive the rotary vane engine, including crude oil and dried wood.
Approximately one third-of the energy released in an Otto-cycle engine by the combustion of fuel can exit the engine as unused energy via the engine exhaust. Some of this energy could be recovered if the expansion ratio within the engine's cylinders could be made greater than the compression ratio. Because compression and expansion occur in the same cylinder in an Otto-cycle engine, achieving different expansion and compression ratios would require that the compression process begin under a partial vacuum. Starting the compression process under a partial vacuum, however, would substantially reducing the overall power produced by the engine. The compression and expansion processes in rotary vane engine systems, by contrast, can be performed in separate mechanical devices that readily facilitate the use of different compression and expansion ratios.
The combustion temperature in an Otto-cycle engine is relatively high, which can result in high nitrogen oxide (NOX) emissions. Because NOX is a prime contributor to smog, exhaust gas recycling and other provisions may be needed to reduce the NOX emissions to acceptable levels. Rotary vane engine systems, by contrast, can be configured so that the combustion temperature can be continuously varied, thereby facilitating lower NOX emissions and increased fuel efficiency.
The dwell time of the fuel-air mixture in an Otto-cycle engine, in general, is relatively short, particularly at high engine speeds. The short dwell time can result in unburned fuel exiting the exhaust, potentially resulting in unsatisfactory emission levels and necessitating the use of a catalytic converter or other pollution-control devices. The dwell time of the fuel in a rotary vane engine systems can be substantially longer than in an Otto-cycle engine, thereby promoting complete combustion of the fuel.
The compression ratio in typical diesel-cycle engines can be approximately 20:1. Fuel is sprayed into each cylinder after the air therein is compressed, and the resulting fuel-air mixture is combusted. Diesel engines have no throttle to limit intake the intake pressure below ambient, and the expansion ratio in a typical diesel-cycle engine is usually about equal to the compression ratio. The relatively high compression ratio in diesel engines can result in relatively high NOX emissions. The compression and expansion processes in rotary vane engine systems, as discussed above, can be performed in separate mechanical devices that readily facilitate the use of a compression ratio that is lower than the expansion ratio.
Moreover, the dwell time of the fuel-air mixture in a diesel-cycle engine is relatively short. Although additives such as cetane improvers can be introduced into the fuel to hasten the combustion process, incomplete combustion manifested as soot in the engine exhaust is common in diesel-cycle engines. The dwell time of the fuel in a rotary vane engine systems can be substantially longer than in a diesel-cycle engine, thereby promoting complete combustion of the fuel.
Diesel fuels typically have a relatively high boiling point, which can inhibit the tendency of the fuel to vaporize. Accordingly, diesel fuel is usually injected into the cylinder as a high-pressure spray to facilitate vaporization. The equipment needed to control and otherwise facilitate the fuel injection process can be relatively complex and expensive, however, due to need to vary the amount of fuel injected as the speed and timing of the engine change. Rotary vane engines, as discussed above, can generally use any type of fuel that releases sufficient energy during combustion to drive the rotary vane engine, and the relatively long dwell-time of the fuel-air mixture in rotary vane engine systems can promote complete combustion of the fuel.
Diesel and Otto-cycle engines typically require some type of liquid or air cooling. The energy transferred out of the engines as heat during the cooling process represents an energy loss. The need to cool diesel and Otto-cycle engines results in part from the use of lubricants within the engines. In particular, most lubricants degrade at the operating temperatures of a typical diesel or Otto-cycle engine, thereby necessitating engine cooling to avoid subjecting the lubricants to excessive temperatures. Rotary vane engine systems, by contrast, can operate at temperatures that are less than half the operating temperature of a typical diesel or Otto-cycle engine. Thus, the cooling requirements for rotary vane engine systems, and the energy losses associated therewith, are usually less than those of a diesel or Otto-cycle engine. Moreover, the relatively low operating temperatures of rotary vane engine systems can eliminate the need for a lubrication system in some applications.
The combustion process in steam and Sterling-cycle engines does not occur in the gas that is expanded to produce a work output. Thus, the efficiency of the heat-transfer process from the fuel to the working fluid is relatively poor. By contrast, the fuel in rotary vane engine systems is mixed and combusted with the air that is to be expanded. Thus, nearly all of the energy released from the fuel during combustion can be used to heat the working fluid.
Gas turbine engines typically use a turbine that extracts energy from a high-pressure, high-temperature gas by impulse (direction change), reaction (acceleration), or a combination thereof. The turbine typically operates at relatively high rotational speeds, to avoid excessive by-pass of the gas past the turbine blades and the accompanying energy losses. The expanding gases in rotary vane engine systems, by contrast, are typically confined by vanes that are able to effectively confine the gases at low rotational speeds.
Rotary vane engine systems may be subjected to operating conditions, e.g., torque outputs, rotational speeds, etc., that vary widely during normal operation. Although rotary vane engine systems possess substantial advantages in relation to other types of engine systems, a typical rotary vane engine system cannot operate optimally, e.g., at maximum thermal efficiency, as it operating conditions vary. Consequently, an ongoing need exists for rotary vane engine systems having operating characteristics that can be optimized as operating conditions vary.
Embodiments of rotary vane engines comprise rotors that rotate about an axis of rotation. The rotors can be moved in directions substantially perpendicular to the axis of rotation to vary expansion and/or compression ratios of the rotary vane engines. The ability to vary the expansion and/or compression ratios can facilitate optimization of the performance of the rotary vane engines as operating conditions vary.
Other embodiments of rotary vane engines comprise a housing; and a rotor mounted in the housing and rotatable in relation to the housing about an axis of rotation. The rotor is movable in relation to the housing in a direction substantially perpendicular to the axis of rotation.
Other embodiments of rotary vane engines comprise a housing; and a rotor mounted for rotation within the housing and comprising a plurality of vanes. The vanes and the housing define a plurality of chambers for expanding a pressurized gas to impart rotation to the rotor. A volume of each of the chambers in relation an angular position of the chamber is variable so that an expansion ratio of the pressurized gas can be varied.
Other embodiments of rotary vane engines comprise a housing; and a rotor mounted within the housing and rotatable in relation to the housing about an axis of rotation. The rotor comprises a shaft and plurality of vanes mounted on the shaft. The vanes and the housing defining a plurality of chambers each having a volume that receives a pressurized gas. The rotary vane engines further comprise at least one of: a hydraulic actuator; a screw jack; a pneumatic cylinder; a cam; a ramp; and a lobe coupled to the rotor for moving the rotor in a direction substantially perpendicular to the axis of rotation so that a volume of the chambers in relation to an angular position of the chambers can be varied.
The foregoing summary, as well as, the following detailed description of preferred embodiments, are better understood when read in conjunction with the appended drawings. The drawings are presented for illustrative purposes only, and the scope of the appended claims is not limited to the specific embodiments shown in the drawings. In the drawings:
The engine system 10 also includes a rotary vane motor 26, shown in
The compressor 22 provides compressed air to the air storage tank 23. The direction of flow of the compressed air, and the high-temperature, pressurized gas subsequently produced in the combustor 24 when the air is mixed with fuel and burned, are denoted in the figures by the reference character “F.”
The compressor 22 can be, for example, a piston and cylinder compressor; a lobe compressor; a sliding vane compressor; a Wankel-type rotor or rotary screw compressor; or any other type of compressor suitable for providing compressed air to the combustor 24. The compressor 22 can be driven, for example, by a separate electric motor, gears from the expander output shaft, or other suitable means.
An exhaust source 28, designated in phantom in
The compression ratio of the compressor 22 is within the range of approximately 10:1. This particular range of compression ratios is specified for exemplary purposes only; the optimal compression ratio or range or compression ratios is dependent upon the requirements of the rotary vane motor 26, which in turn can vary with factors such as the required torque for the rotary vane motor 26 in a particular application.
The compressor 22 can be formed from one or more self-lubricating materials such as a carbide, nitride or boride; or an oxide of a material such as aluminum, silicon, titanium, vanadium, tungsten, or zirconium. The compressor 22 can be formed from materials other than self-lubricating materials in alternative embodiments.
The combustor 24 has a combustion chamber 30, shown in
The engine system 10 can also include a fuel source 32 in fluid communication with the combustion chamber 30, and an ignition source or igniter 34 located in or proximate the combustion chamber 30, as shown in
The mixture of air and combustion products produced in the combustion chamber 30 is hereinafter referred to as “the working fluid.”
The air storage tank 23 provides a reserve of compressed air that can help ensure that the combustor 24 is adequately supplied with air during periods of peak demand, such as when the rotary vane motor 26 is accelerating. Alternative embodiments can be configured without the air storage tank 23, i.e., the compressor 22 can provide compressed air directly to the combustor 24 in alternative embodiments.
The rotary vane motor 26 comprises an outer casing 54, and a housing 46 mounted within the outer casing 54 as shown in
The housing 46 has an inlet 50 formed therein, as shown in
The housing 46 also has an outlet 52 formed therein. The working fluid exits the housing 46 by way of the outlet 52 after being expanded as discussed below.
The outlet 52 is offset from the inlet 50 so that the outlet 52 and the inlet 50 are spaced apart circumferentially by more than 180°, as shown in
The inventor has found that the optimal, i.e., maximum, sealing between the tips of the vanes 58 and the interior surface 48 of the housing 46 occurs when the vanes are proximate the six o'clock position, from the perspective of
A plurality of vent openings 56 can be formed in the left side of the housing 46 (from the perspective or
The rotary vane motor 26 also comprises a rotor 44 positioned in the chamber 49 within the housing 46, as shown in
The rotor 44 is mounted on the shaft 45, so that the rotor 44 rotates within the chamber 49 about the longitudinal axis T. The rotor 44 can be connected to a load 27, depicted in
The rotor 44 comprises a plurality of radially-oriented vane guides 58 that extend in a direction substantially perpendicular to the longitudinal axis T of the shaft 45, as shown in
The rotor 44 further comprises a plurality of vanes 62. Each vane 62 is positioned within a vane slot 60 of an associated one of the vane guides 58. The vanes 62 and the vane guides 58 each have a substantially rectangular shape. The vanes 62 and the vane guides 58 can have a shape other than rectangular in alternative embodiments.
The rotor 44 is depicted with twelve of the vanes 62 and twelve of the vane guides 58 for exemplary purposes only. Alternative embodiments can include more, or less than twelve vanes 62 and twelve vane guides 58. The optimal number of vanes 62 and vane guides 58 is application-dependent, and can vary with factors such as cost limitations, the desired efficiency and torque output of the rotary vane motor 26, etc.
Each vane slot 60 has a width, denoted by the reference character “W” in
Each vane guide 58 has a height, or radial dimension, denoted by the reference character “H” in
The tip of each vane 62 can be rounded as depicted in
The rotary vane motor 26 also comprises a first end plate or cover 64, as shown in
The housing 46 and one or both of the first and second covers 64, 66 can be unitarily formed in alternative embodiments. The first cover 64 and/or the second cover 66 can have vent openings (not shown) formed therein in addition to, or in lieu of the vent openings 56 in the housing 46.
The first cover 64 has an opening 65 formed therein, as shown in
The rotary vane motor 26 also comprises a ring 67, as shown in
The ring 67 has an opening 69 formed therein, as shown in
Another ring 67 can be positioned between the rotor 44 and the second cover 66 as shown in
Other types of suitable seals, such as labyrinth seals, can be used in lieu of the rings 67 in alternative embodiments. Moreover, the rings 67 can be mounted on springs 75 in alternative embodiments, as shown in
A plurality of radially-oriented chambers 68 are formed within the rotary vane motor 26, as shown in
The rotor 44 rotates in a counterclockwise direction from the perspective of
A barrier 47 can be positioned within each of the inlet 50 and the outlet 52 to prevent the vanes 62 from sliding out of the housing 46 as the vanes 62 rotate past the inlet 50 and the outlet 52, as shown in
The shaft 45 can be positioned so that its axis T is offset from a central axis “S” of the housing 46, as shown in
The rotor 44 rotates in response to the expansion of the working fluid in the chambers 68. In particular, the working fluid enters each chamber 68 via the inlet 50 as the chamber 68 rotates past the inlet 50. As discussed above, the working fluid is in a compressed, i.e., unexpanded, state when it is supplied to the inlet 50 from the combustor 24. Thus, each chamber 68 is filled with a charge of unexpanded working fluid as the chamber 68 rotates past the inlet 50.
The volume of each chamber 68 is at or near its minimum as the chamber 68 rotates past the inlet 50, when the rotor 44 and the housing 46 are in the relative positions depicted in
Optimally, the working fluid in the chamber 68 has expanded so that its pressure and temperature are close to ambient by the time the chamber 68 reaches the outlet 52. The amount of energy extracted from the working fluid at or near maximum when the working fluid is expanded in this manner.
At least some of the expanded working fluid in each chamber 68 exits the chamber 68 and is exhausted from the housing 46 by way of the outlet 52 as the chamber 68 rotates past the outlet 52. If desired, heat from the exhaust can be exchanged with the compressed air entering the combustor 24, with the working fluid entering the rotary vane motor 26 from combustor 24, or with the working fluid at other stages within the cycle, to help optimize the thermal efficiency of the engine system 10.
The vanes 62 surrounding each chamber 68 are forced inward, into their corresponding vane guides 58, as the chamber 68 rotates between the outlet 52 and the inlet 50 due to the decreasing spacing between the shaft 45 and the interior surface 48 of the housing 46. The volume of the chambers 68 thus decreases as the chambers 68 approach the inlet 50.
Each chamber 68 passes the vent openings 56 as the chamber 68 rotates away from the outlet 52 and toward the inlet 50. The vent openings 56 help to control the pressure within the chambers 48 as the chambers 48 approach the inlet 50. In particular, the vent openings 56 permit residual working fluid in the chamber 68 to escape from the chamber 68 as the volume of the chamber 68 is reduced. Venting the chamber 68 in this manner prevents the residual working fluid within the chamber 68 from being compressed to levels that could prevent the unexpanded working fluid supplied by the combustor 24 from entering the chamber 68 when the chamber 68 reaches the inlet 52.
The partially-compressed working fluid vented by way of the vent openings 56 can be directed to one or more of the ports 57, and introduced into the chambers 68 in which the expansion portion of the cycle is occurring. In particular, the motor system 10 can include a manifold 89, shown in
The controller 76 can be programmed to provide control inputs to the manifold 89 that cause the manifold 89 to port the residual working fluid vented through the vent openings 56 to an appropriate one of the ports 67. The residual working fluid vented via a particular vent opening 56 can be routed to a port 57 that will direct the working fluid into a chamber 68 containing unexpanded or partially expanded working fluid at a similar pressure. The vented working fluid, once being introduced into the chamber 68 by way of the appropriate port 57, can be expanded along with the working fluid already in the chamber 68. At least some of the energy expended in compressing the vented working fluid can thereby be recovered and used in the cycle.
The housing 46 is depicted with four of the ports 57 for exemplary purposes only. Alternative embodiments can include more, or less than four ports 57.
The working fluid vented from the chambers 48 by way of the vent openings 56 can be vented directly to the ambient environment in alternative embodiments, without the use of manifold 89. In other alternative embodiments, some or all of the vented working fluid can be directed to accessories or other components, such as air-actuated shock absorbers and springs, tire inflation means, power trunk lifters, ash removal means for filters, that require a source of pressurized gas, using the manifold 89 or another suitable means for controlling the flow of the residual working fluid.
The spacing between the inlet 50 and the adjacent vent opening 56 is sufficient to ensure that the chambers 48 are not exposed to both the inlet 50 and the adjacent vent opening 56 at the same time. This feature helps to ensure that the chamber 68 is not vented as it is being filled with the unexpanded working fluid from the combustor 24.
The housing 46 is depicted with four of the vent openings 56 for exemplary purposes only. Alternative embodiments can include more, or less than four vent openings 56.
Upon reaching the inlet 50, each chamber 68 is filled with another charge of unexpanded working fluid and the above-noted cycle is repeated during the subsequent revolution of the rotor 44. The continuous stream of working fluid supplied to the chambers 68 as the chambers 68 pass the inlet 50, and the subsequent expansion thereof, cause the rotor 44 and the attached shaft 45 to rotate on a continuous basis, in the direction denoted by the arrow “R” in
The rotary vane engine 26 can be used as the source of compressed air for the system 10 in alternative embodiments, thereby alleviating the need for the compressor 22. To facilitate this use, an opening 73 can be formed in each of the first and second covers 64, 66 proximate the outer peripheries thereof, as shown in
The vane guides 58 and the vanes 62 can be angled in their respective lengthwise directions in relation to the centerline of the shaft 45 in alternative embodiments, as shown in
The housing 46 and the rotor 44 can be made from one or more self-lubricating materials such as a carbide, carbo-nitride, nitride, or boride; or an oxide of a material such as aluminum, silicon, titanium, vanadium, tungsten, or zirconium. A diamond coating or other suitable coating can be applied to the housing 46 and/or rotor 44, if desired. The use of self-lubricating materials can eliminate the need for oils, greases, or other lubricants. Such lubricants can present a slip and fall hazard, and can necessitate periodic clean-up. Moreover, lubricants typically require some type of cooling to prevent thermally-induced degradation. The use of lubricants can thus necessitate the use of cooling means such as a radiator or cooling fins. Moreover, the thermal energy transferred out of the rotary vane motor 26 by the cooling means represents an energy loss that lowers the overall thermal efficiency of the engine system 10. Hence, eliminating the need for lubricants through the use of self-lubricating materials can provide certain advantages.
The housing 46 and the rotor 44 can be formed from materials other than self-lubricating materials in alternative embodiments. For example, the housing 46 and the rotor 44 can be formed from non-self-lubricating materials treated with a lubricating compound such as NEVER-SEEZE®. Other alternative embodiments can be equipped with a lubrication system.
The shaft 45 can be moved in a direction substantially perpendicular to the shaft axis T, as discussed above. In particular, the rotary vane motor 26 comprises four hydraulic actuators 74 that support and constrain the bearing 72 and the shaft 45. Two of the hydraulic actuators 74 are visible in
A second end of each hydraulic actuator 74 is connected to the outer casing 54 by a pin or other suitable means that permits the hydraulic actuator 74 to pivot in relation to the outer casing 54, about an axis that is substantially parallel to the central axis “S” of the housing 46.
The noted mounting arrangement of the shaft 45 facilitates movement of the shaft 45 and the attached rotor 44 in directions substantially perpendicular to the central axis “S” of the housing 46. In particular, the shaft axis T, which is the axis of rotation of the rotor 44, can be moved into, and within each of four quadrants within the housing 46 designated I, II, III, and IV in
The hydraulic actuators 74 can be mechanically coupled to the bearing 72 and the outer casing 54 by a means other than stationary pins in alternative embodiments. For example, alternative embodiments can be equipped with races. Each race can receive a corresponding pin mounted on the first or second end of the hydraulic actuators 74. The pins can move back and forth within the races to facilitate movement of the hydraulic actuators 74 in relation to the outer casing 54 and the bearing 72.
The position of the rotor 44 in relation to the central axis S of the housing 46 affects the volume of the chambers 68 at a given circumferential, or clock position as the chambers 68 rotate about the shaft axis T. The volume of chambers 68 at a given clock position affects the expansion ratio of the working fluid within rotary vane motor 26, which in turn can influence the operating characteristics, e.g., thermal efficiency, torque output, etc., of the engine system 10.
For example, moving the shaft axis T downward from its centered position, as depicted in
Moving the shaft axis T into quadrant II from a position substantially coincident with the central axis S of the housing 46 will generally maximize the torque output of the rotary vane motor.
The shaft axis T can be moved into quadrant IV when it is desired to maximize the amount, i.e., the flow-rate, of pressurized air that can be extracted from the rotary vane motor 26 via the vent openings 56.
The shaft axis T can be moved into quadrant III when the rotary vane motor 26 is idling, to minimize fuel consumption during idle, i.e., no load, operation.
The engine system 10 can also include a source of pressurized hydraulic fluid 77 in fluid communication with the head and rod ends of each hydraulic actuator 74, as shown in
The source of pressurized hydraulic fluid 77 includes valving 79 that selectively directs the pressurized hydraulic fluid to the head and rod ends of each hydraulic actuator 74, to effectuate extension and retraction of the hydraulic actuator 74. The valving 79 is depicted diagrammatically in
The engine system 10 can further include a controller 76, depicted in
The controller 76 is communicatively coupled to the valving 79 of the source of pressurized hydraulic fluid 77. The controller 76 is programmed to control the extension and retraction of the hydraulic actuators 74 in a coordinated manner so as to effectuate movement of the shaft 45 and the rotor 44 in a desired direction into, or within one of the quadrants I, II, III, or IV, to alter the expansion ratio of the rotary vane motor 26.
The controller 76 can receive inputs relating to various operating parameters of the engine system 10, including the position of the shaft 45 and/or the rotor 44, and can control the operation of the engine system 10 based on the inputs. For example, the controller 76 can receive inputs from a torque sensor that provides an indication of the output torque being transmitted by the shaft 45; a speed sensor that provides an indication of the rotational speed of the rotor 44; temperature and pressure sensors that provide indications of the pressure and temperature with one or more of the chambers 68; etc. These sensors are denoted collectively in
The controller 76 can be programmed to function as closed-loop controller that adjusts selected operating parameters, e.g., fuel flow and airflow to the combustor 24, to achieve a desired operating condition, e.g., a desired torque output. The controller 76 can simultaneously control the position of the rotor 44 to achieve an optimal expansion ratio for a particular set of inputs. The use of a closed-loop control methodology is specified for exemplary purposes only; other types of control methodologies can be used in the alternative.
Each hydraulic actuator 74 can be equipped with a position sensor 85 or other means that provides an indication to the controller 76 of the extent to which the hydraulic actuator 74 is extended. The position sensors 85 are depicted in
During operation of the engine system 10, the compressor 22 supplies pressurized air to the air-storage tank 23. The pressurized air is directed from the air-storage tank 23 to the combustor, where the air is mixed with fuel and burned continuously to produce a stream of high-pressure, high-temperature working fluid.
The working fluid enters rotary vane motor 26 by way of the inlet 50. A charge of the high-pressure, high-temperature working fluid enters each individual chamber 68 of the rotary vane motor 26 as the chamber 68 rotates past the inlet 50. The vanes 62 associated with chamber 68 may be partially or fully extended from their associated vane guides 58 as the chambers 68 pass the inlet 50, depending on the position of the rotor 44 in relation to the housing 46.
The working fluid, after entering the chamber 68, expands as the chamber subsequently rotates away from the inlet 50, thereby imparting a rotational force to the rotor 44. The rotation of the rotor 44 subjects the vanes 62 that define the chamber 68 to a centrifugal force that urges the vanes 62 in an outward direction, so that the volume of the chamber 68 increases. Moreover, the centrifugal force urges the outer edges of the vanes 62 against the interior surface 48 of the housing 46. Under optimal conditions, the expansion of the working fluid continues until the working fluid has been expanded to a pressure slightly above ambient. The expanded working fluid is exhausted from the chamber 68 as the chamber 68 rotates past the outlet 52.
The vanes 62 may be partially or fully retraced into their associated vane guides 58 as the chamber 68 rotates toward the inlet 50 after passing the outlet 52, depending on the position of the rotor 44 in relation to the housing 46. The volume of the chamber 68 thus decreases as the chamber rotates toward the inlet 50. The housing 46 can have vent openings 56 formed therein, at circumferential locations between the outlet 52 and the inlet 50. Residual working fluid can vent from the chambers 68 by way of the vent openings 56 as the chambers 68 pass the vent openings 56. Venting of the residual working fluid helps to ensure that the pressure in the chamber 68 is low enough when the chamber 68 reaches the inlet 50 to permit a new charge of high-temperature, high-pressure working fluid to enter the chamber 68.
The continuous stream of working fluid supplied to the chambers 68 as the chambers 68 pass the inlet 50, and the subsequent expansion thereof, cause the rotor 44 and the attached shaft 45 to rotate on a continuous basis. The shaft 45 can provide torque to a device, such as an electrical generator or an automotive transmission, connected thereto.
The rotor 44 can be moved in directions substantially perpendicular to the central axis “S” of the housing 46. Moving the rotor 44 in this manner can alter the relationship between the volume and clock position of the chambers 68, which in turn can affect to expansion ratio of the rotary vane motor 26. The expansion ratio can be varied by the controller 76 so as to optimize one or more operating parameters of the rotary vane motor 26 at a given operating condition. Thus, the operation of the rotary vane motor 26 can be optimized over a range of operating conditions. In alternative embodiments in which the rotary vane motor 26 is used to compress the working fluid, the compression ratio can be varied along the with expansion ratio in a manner that optimizes the operation of the rotary vane motor 26.
The foregoing description is provided for the purpose of explanation and is not to be construed as limiting the invention. Although the invention has been described with reference to preferred embodiments or preferred methods, it is understood that the words which have been used herein are words of description and illustration, rather than words of limitation. Furthermore, although the invention has been described herein with reference to particular structure, methods, and embodiments, the invention is not intended to be limited to the particulars disclosed herein, as the invention extends to all structures, methods and uses that are within the scope of the appended claims. Those skilled in the relevant art, having the benefit of the teachings of this specification, can make numerous modifications to the invention as described herein, and changes may be made without departing from the scope and spirit of the invention as defined by the appended claims.
For example, the rotor 44 of the rotary vane motor 26 is cantilevered from a single support point, i.e., the bearing 72. Supporting the rotor 44 in this manner can help to minimize the overall length of the rotary vane motor 26. The rotor 44 can be supported in other ways in alternative embodiments. For example, the shaft 45 can be lengthened so as to extend forwardly through the second cover 66, and a second bearing 72 can be added so that the rotor 44 is suspended between the two bearings 72. If desired, the forward portion of the lengthened shaft 45 can be connected to an auxiliary load, such as an alternator or pump of a motor vehicle. Supporting the shaft 45 from two or more points can allow the shaft 45 and the bearings 72 to be made smaller and lighter in relation to embodiments in which the shaft 45 is cantilevered from a single support point.
The rotary vane motor 26 is depicted with four of the hydraulic actuators 74 for exemplary purposes only. Alternative embodiments can be configured with more, or less than four hydraulic actuators 74. For example, alternative embodiments can include two hydraulic actuators 74 positioned in an opposing relationship. This arrangement can facilitate movement of the rotor 44 in a single linear direction. For example, the two actuators 74 can be oriented vertically from the perspective of
Other alternative embodiments can use screw jacks, pneumatic cylinders, cams, ramps, lobes, or other suitable actuation means in lieu of the hydraulic actuators 74. Moreover, the hydraulic actuators 74 or other actuation means can be located outside of the outer casing 54 in other alternative embodiments.
The vanes 302 and/or the front cover 306, rear cover 308, and housing 303 (or the contacting surfaces thereof) can be formed from a self-lubricating material such as silicon carbide. Alternatively, the vanes 302 and/or the front cover 306, rear cover 308, and housing 303 can be formed from a relatively inexpensive material such as steel, and a suitable lubricant such as NEVER-SEEZE® can be sprayed onto the contacting surfaces of the vanes 302, the front and rear covers 306, 308, and the housing 303 on an intermittent basis during operation of the motor 300.
Each vane 322 is split. In particular, each vane 322 comprises a first portion 330 and a second portion 332. The first and second portions 330, 332 are configured so that the second portion 332 is nested partially within the first portion 330, and can slide forward and rearward, i.e., left-right from the perspective of
The interior of the first portion 330 of the vane 322 can be filled with compressed air that urges the second portion 332 rearward, toward the rear cover 328, in relation to the first portion 330. This feature causes the forward edge of the first portion 330 and the rearward edge of the second portion 332 to remain in contact with the adjacent surfaces of the respective front cover 326 and rear cover 328 as the vane 322 and the adjacent surfaces wear, thereby maintaining a seal between the vane 322 and the adjacent surfaces. The forward edge of the first portion 330 and the rearward edge of the second portion 332 are depicted in
Compressed air can be ducted to the interior of the first portion 330 of the vane 322 by way of the interior of the shaft 325, and an opening 335 formed in the shaft 325 adjoining the interior of the first portion 330. The compressed air can be vented from the interior of the first portion 330 by way of an opening 337 formed in the first portion 330.
The second portion 332 of each vane 322 can be biased in the rearward direction by springs located within the first portion 330, in lieu of compressed air.
The vanes 322 and/or the front cover 326 and rear cover 328 (or the contacting surfaces thereof) can be formed from a self-lubricating material such as silicon carbide. Alternatively, the vanes 322 and/or the front cover 326 and rear cover 328 can be formed from a relatively inexpensive material such as steel, and a suitable lubricant such as NEVER-SEEZE® can be sprayed onto the contacting surfaces of the vanes 302, the front rear cover 326, and the rear cover 328 on an intermittent basis during operation of the motor 320.
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