Turbine apparatus with counter-rotating blades

A turbine apparatus has a main shaft, a first set of blades mounted to the main shaft, a second set of blades, and a barrel affixed to a periphery of the second set of blades. The barrel is rotatably mounted independent of a rotation of the main shaft. The barrel and the second set of blades rotates in a direction opposite to the direction of rotation of the first set of blades and the main shaft. A third set of blades is mounted to the main shaft such that the second set of blades is interposed between the first and third sets of blades. An outer shell extends over and an outer surface of the barrel such that the barrel is rotatable interior of the outer shell.

CROSS-REFERENCE TO RELATED APPLICATIONS

Not applicable.

Not applicable.

NAMES OF THE PARTIES TO A JOINT RESEARCH AGREEMENT

Not applicable.

Not applicable.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to turbines. More particularly, the present invention relates to steam turbines, gas turbines, process turbines and gas compressors. More particularly, the present invention relates to such turbines where adjacent sets of blades are counter-rotatable with respect to each other.

A steam turbine is a device that extracts thermal energy from pressurized steam and uses it to do mechanical work on a rotating output shaft. Because the turbine generates rotary motion, it is particularly suited to be used to drive an electrical generator. Approximately 90% of all electrical generation in the United States is by the use of steam turbines. The steam turbine is a form of heat engine that derives much of its improvement in thermodynamic efficiency from the use of multiple stages in the expansion of the steam. Steam turbines are made in a variety of sizes ranging from small (i.e. less than 0.75 kW) to approximately 1,500,000 kW. The small units are used as mechanical drives for pumps, compressors and other shaft-driven equipment. Large turbines are used to generate electricity.

Turbine blades are of two basic types, blades and nozzles. Blades move entirely due to the impact of steam on them. Their profiles do not converge. This results in a steam velocity drop and essentially no pressure drop as steam moves through the blades. A turbine composed of blades alternating with fixed nozzles is called an impulse turbine, a Curtis turbine, a Rateau turbine, or a Brown-Curtis turbine. Nozzles appear similar to blades, but their profiles converge near the exit. This results in a steam pressure drop and velocity increase as steam moves through the nozzles. Nozzles move due to both the impact of steam on them and the reaction due to the high-velocity steam at the exit. A turbine composed of moving nozzles alternating with fixed nozzles is called a reaction turbine or a Parsons turbine.

Except for low-power applications, turbine blades are arranged in multiple stages in series, called compounding, which greatly improves efficiency at low speeds. A reaction stage is a row of fixed nozzles followed by a row of moving nozzles. Multiple reaction stages divide the pressure drop between the steam inlet and exhaust. Numerous small drops result in a pressure-compounded turbine. Impulse stages may be either pressure-compounded, velocity-compounded, or pressure-velocity compounded. A pressure-compounded impulse stage is a row of fixed nozzles followed by row of moving blades, with multiple stages for compounding. A velocity-compounded impulse stage is a row of fixed nozzles followed by two or more rows of moving blades alternating with rows of fixed blades. This divides the velocity drop across the stage into several smaller drops.

Condensing turbines are most commonly found in electrical power plants. These turbines exhaust steam from a boiler in a partially condensed state at a pressure well below atmospheric to a condenser. Non-condensing or back pressure turbines were most widely used for process steam applications. The exhaust pressure is controlled by a regulating valve to suit the needs of the process steam pressure. These are commonly found at refineries, district heating units, pulp and paper plants, and desalination facilities where large amounts of low-pressure process steam are needed. Reheat turbines are also almost used exclusively in electrical power plants. In a reheat turbine, steam flow exits from a high-pressure section of the turbine and is returned to the boiler where additional superheat is added. The steam goes back into an intermediate pressure section of the turbine and continues its expansion. Using reheat in a cycle increases the work output from the turbine and also the expansion reaches conclusion before the steam condenses. As such, this minimizes the erosion of the blades in the last rows. Extracting-type turbines are common in various applications. In an extracting-type turbine, steam is released from the various stages of the turbine and used for industrial process needs or sent to boiler feedwater heaters to improve overall cycle effect efficiency. Induction turbines introduce low-pressure steam at an intermediate stage to produce additional power.

A gas compressor is a mechanical device that increases the pressure of the gas by reducing its volume. Compressors are similar to pumps. Both increase the pressure on a fluid and both can transport the fluid through a pipe. Since gases are compressible, the compressor also reduces the volume of the gas. Axial-flow compressors are dynamic rotating compressors that use arrays of fan-like airfoils to progressively compress the working fluid. The arrays of airfoils are set in rows, usually as pairs, one rotating and one stationary. The rotating airfoils, also known as blades or rotors, accelerate the fluid. The stationary airfoils, also known as stators or vanes, decelerate and redirect the flow direction of the fluid preparing it for the rotor blades at the next stage. Axial compressors are almost always multi-stage, but the cross-sectional area of the gas passage diminishes along the compressor to maintain an optimal axial Mach number.

In such turbines, a fluid stream, under pressure, impinges on a set of blades (or buckets) connected to a central shaft to produce work. This results in changes in the angular velocity of the fluid stream. These changes in an angular velocity serve to strike the next set of blades connected to the shaft in the most efficient manner. There is an intermediate set of blades which are set at a different angle to realign the flow so as to impinge upon the next set of working blades at the most efficient angle. The set of intermediate blades in most equipment is currently fixed to the stationary element. This process uses approximately 40% of the working fluid energy without producing any work.

In the past, various patents and patent publications have issued relating to such turbines. For example, U.S. Pat. No. 4,648,788, issued on Mar. 10, 1987 to P. Jochum, describes a device and a fluid pressure generator that includes an annular casing which is peripherally mounted and driven in a through-flow channel. The interface of the annular casing forms part of the wall of the through-flow channel. The annular casing is provided with a number of propeller blades which extend radially inwardly into the through-flow channel and which are rotationally mounted on their individual pin shafts by means of which the magnitude of the thrust may be altered in a continuous manner and the direction of the operation of the thrust can be reset.

U.S. Pat. No. 4,969,325, issued on Nov. 13, 1992 Adamson et al., shows a turbofan engine having a counter-rotating partially-geared fan drive turbine. This turbofan engine has a fan section, a booster compressor disposed aft of the fan section relative to the flow of combustion gases through the engine, and a core section disposed aft the booster compressor. A low-pressure counterrotating turbine, disposed aft the core section, is used for driving the fans section and the booster compressor. The counterrotating turbine includes at least one set of rotating turbine blades and at least one set of oppositely rotating counterrotating turbine blades. A twin spool shaft is provided for coupling the turbine blades to the booster compressor and for coupling the counterrotating turbine blades to the fans section.

U.S. Pat. No. 6,278,197, issued on Aug. 21, 2001 the K. Appa, discloses a contra-rotating wind turbine system. A hub assembly is provided having inner and outer coaxial shafts telescopically related but radially spaced to permit independent rotation about a generally horizontal axis. A first set of rotor blades is mounted on the inner shaft at a plurality of circumferentially-spaced locations. The rotor blades extend radially away from the axis of rotation and positioned on the inner shaft for rotating the inner shaft in a first direction about the axis of rotation when subjected to wind-induced airflow. A second set of rotor blades is similarly mounted on the outer shaft axially spaced from the first set of rotor blades for rotating the outer shaft about the axis of rotation in an opposite direction.

U.S. Pat. No. 7,195,446, issued a Mar. 27, 2007 to Seda et al., provides a counter-rotating turbine engine that provides a low-pressure turbine inner rotor configured to rotate in a first direction and a low-pressure turbine outer rotor configured to rotate in a second direction that is opposite to the first rotational direction. At least one foil bearing is coupled to at least one of the inner and outer rotors so as to improve clearance control between a first rotating component and at least one of a second rotating component and a non-rotating component.

U.S. Pat. No. 7,290,386, issued on Nov. 6, 2007 to Orlando et al., teaches a counter-rotating gas turbine engine. A low-pressure turbine inner rotor includes a first plurality of turbine blade rows configured to rotate in a first direction and a low-pressure turbine outer rotor rotatably coupled to the inner rotor. The outer rotor includes a second plurality of turbine blade rows that are configured to rotate in a second direction that is opposite the first rotational direction of the inner rotor such that at least one of the second plurality of turbine blade rows is coupled axially forward of the first plurality of turbine blade rows.

U.S. Pat. No. 7,451,592, issued on Nov. 18, 2008 to Taylor et al., teaches a counter-rotating turbine engine which includes a gearbox. The turbine engine arrangement is provided with contra-rotating shafts and a gearbox which is also coupled to a shaft. The relative rotational speed ratio between the shafts can be determined with a first low-pressure turbine secured to the first shaft arranged to rotate at a lower speed but provide high work whilst a second low-pressure turbine secured to the second shaft rotates at a higher speed governed by the gearbox.

U.S. Pat. No. 8,393,853, issued on Mar. 12, 2013 to Sauer et al., provides a high-efficiency turbine and method of generating power. The turbine includes a plurality of blades that rotate in a single direction when exposed to a fluid flow. The plurality of blades are joined to the central shaft by a plurality of radial spokes disposed substantially perpendicular to the central shaft such that the rotating plurality of blades causes the shaft to rotate.

U.S. Patent Publication No. 2012/0049523, published on Mar. 1, 2012 to S. A. Bersiek, describes a wind jet turbine with fan blades located on an inner and outer surface of the cylinder so as to allow wind or liquid to pass through the inner and outer blades. The wind jet turbine has a first set of fan blades, a plurality of magnets that each has a magnetic field, a cylinder having an inside and outside surface that supports the first set of fan blades on the inside surface and coupled to the plurality of magnets, and at least one cable winding located apart from the magnets. The rotation of the cylinder results in the movement of the magnetic field across at least one cable winding.

U.S. Patent Publication No. 2013/0219859, published in Aug. 29, 2013 to Suciu et al., provides a counter-rotating low-pressure compressor and turbine. The compressor section includes a counter-rotating low-pressure compressor that includes outer and inner compressor blades interspersed with one another and configured to rotate in opposite directions to one another about an axis of rotation. A transmission couples at least one of the outer and inner compressor blades to a shaft. The turbine section includes a counter-rotating low-pressure turbine having an outer rotor that includes an outer set of turbine blades. An inner rotor has an inner set of turbine blades interspersed with the outer set of turbine blades. The outer rotor is configured to rotate in an opposite direction about the axis of rotation from the inner rotor. A gear system couples at least one of the outer and inner rotors to the shaft.

U.S. Patent Publication No. 2013/0230380, published on Sep. 5, 2013 to Allouche et al., discloses a rotating housing turbine. The housing has a side wall. The turbine blades are attached to the side wall. The turbine is completely open in the center so as to allow a space for solids and debris to be directed out of the turbine without jamming the spinning blades/side wall.

It is an object of the present invention to provide a turbine apparatus that uses a greater percentage of the energy of the working fluid.

It is another object of the present invention to provide a turbine apparatus that can be used so as to power components are directed back to primary driven equipment.

It is another object of the present invention to provide a steam turbine that is suitable for powering boiler feed pumps, auxiliary pumps, hydraulics, and electrical generators.

BRIEF SUMMARY OF THE INVENTION

The present invention is a turbine apparatus that comprises a main shaft, a first set of blades mounted to the main shaft, a second set of blades, and a barrel affixed to a periphery of the second set of blades. The barrel is rotatably mounted independently of a rotation of the main shaft.

A third set of blades is mounted to the main shaft. The second set of blades is interposed between the first and third sets of blades. The first and third sets of blades are rotatable in a direction opposite to a direction that the second set of blades rotate.

A means is provided for transferring rotational energy of the second set of blades and the barrel to a power source, such as an electrical generator, a boiler feed pump, a compressor, a water pump, a hydraulic unit, and other items. An outer shell extends over an outer surface of the barrel. The barrel is rotatable interior of the outer shell. The power source is connected the main shaft such that rotation of the first set of blades and the main shaft causes the electrical generator to produce a power source.

A fluid inlet is directed toward the first set of blades and within an interior of the barrel. The fluid inlet includes a nozzle for directing a fluid into the interior of the barrel toward the first set of blades. A plurality of fan blades are affixed to the barrel and extend outwardly therefrom. The plurality of fan blades are positioned interior of the outer shell. The means for transferring rotational energy can be a planetary gear arrangement that is connected to the barrel and cooperative with the main shaft or independent of the main shaft so as to transfer energy from the rotation of the barrel to the main shaft or to another shaft.

In the embodiment of the present invention, the barrel can include a first section and a second section. The second section has another set of first blades positioned therein and another second set of blades affixed at a periphery thereof. A fluid inlet is directed to an interior of the barrel in an area between the first section and the second section. An exhaust outlet is positioned rearwardly of the second set of blades. The exhaust outlet is suitable for passing exhaust gases outwardly of the barrel. In this alternative embodiment, the first set of blades has an outer diameter that is less than an outer diameter of the second set of blades. Also, the first set of blades has an outer diameter that is smaller than an outer diameter of the third set of blades.

A fourth set of blades can be provided having an outer periphery affixed to the barrel. The third set of blades is interposed between the second set of blades and the fourth set of blades. The first and third sets of blades rotate in a direction opposite to a direction that the second and fourth set of blades rotate.

The foregoing Section is intended to describe, with particularity, the preferred embodiment of the present invention. It is understood that modifications to this preferred embodiment can be made within the scope of the present invention. As such, this Section should not to be construed, in any way, as limiting of the scope of the present invention. The present invention should only be limited by the following claims and their legal equivalents.

DETAILED DESCRIPTION OF THE INVENTION

Referring toFIG. 1, there shown the turbine apparatus10in accordance with the present invention. The turbine apparatus10includes a first set of blades12, a second set of blades14, a main shaft16, a barrel18, and an outer shell20. InFIG. 1, it can be seen that the first set of blades12is directly mounted to the main shaft14. The second set of blades14is directly mounted, at a periphery thereof, to the barrel18or the housing. The main shaft16extends centrally through the first set of blades12and the second set of blades14. The main shaft16is not connected to the second set of blades14. In the preferred embodiment the present invention, the second set of blades14will rotate in a direction opposite to the second set of blades12and to the direction of rotation of the main shaft16. As a result, the barrel18will rotate in a direction opposite to the rotation of the main shaft16.

InFIG. 1, it can be seen that there is a third set of blades22that is affixed to the main shaft16. The third set of blades22extends in generally parallel relationship to the first set of blades12. The second set of blades14is positioned between the first set of blades12and the second set of blades14. There is a fourth set of blades24that is mounted, at the periphery thereof, to the barrel18. As such, when the first of blades12and the third set of blades22rotate with the rotation of the main shaft16, the second set of blades14and the fourth set of blades24will rotate in the opposite direction. Within the configuration of the present invention, the odd numbered sets of blades will rotate in an opposite direction to that of the even-numbered sets of blades.

A fluid inlet26is directed toward the first set of blades12within the interior of the barrel18. The fluid inlet26includes a nozzle28for directing the fluid into the interior of the barrel18and toward the first set of blades12. The injection of the fluid through the fluid inlet26will impart rotational movement to the first set of blades12. The direction of the blades within the first set of blades12will impart an opposite directional movement to the second set of blades14such that the barrel18will rotate in the opposite direction. The orientation of the blades of the second set of blades14will be directed to the third set of blades22so as to further direct rotational energy toward the third set of blades22. Similarly, the orientation of the blades in the third set of blades22is directed to the fourth set of blades24so as to further enhance the torque applied by the fourth set of blades24to the barrel18.

The shaft16is mounted within bearings and supported by a bearing pedestal30. The bearing pedestal30can be supported upon an underlying surface, such as a floor. The bearing supports the main shaft16in a rotatable configuration. The rotatable shaft16can extend for use exterior of the turbine apparatus10. For example, the main shaft16can extend so as to be linked to a power source, such as an electrical generator, a boiler feed pump, a compressor, a water pump, a hydraulic unit, or other systems that can utilize rotational energy.

The outer shell20extends around the exterior of the barrel18. As such, the interior of the outer shell20is sufficiently sealed so as to avoid loss of pressurized fluid and friction with exterior elements.

As will be described hereinafter, the rotating barrel18can be suitably coupled to allow for the rotation of another shaft or to facilitate the rotation of the main shaft16. For example, the rotating barrel18can be coupled by a gear arrangement to another shaft located adjacent to the main shaft16. Alternatively, a planetary gear arrangement can be coupled between the barrel18in the main shaft16such that rotational energy of the barrel18can be delivered to the main shaft. Still further and alternatively, various rollers, or other connecting devices, can be coupled to the barrel18such that the rotating energy of the barrel18can be delivered for external use.

FIG. 2illustrates, in particular, how the first set of blades12is mounted to the main shaft16. The first set of blades12extends radially outwardly of the main shaft16. The first set of blades12is arranged in a circular configuration so as to have an outer periphery34that is positioned adjacent to but free of the inner wall of the barrel18. The outer shell20is positioned in spaced relation relationship to the outer surface of the barrel18.

FIG. 3illustrates the manner in which the second set of blades14is mounted at the outer periphery thereof to the barrel18. The second set of blades14has an inner surface36that is in spaced relationship to the outer surface of the main shaft16. As a result, the second set of blades14can rotate independently of the rotation of the main shaft16. The outer wall of the barrel18is positioned in spaced relationship to the outer shell20.

The turbine apparatus10of the present invention serves to free the those blades that would be fixed to a stationary member of a conventional turbine apparatus. As such, these free blades are available to produce work. This results in a rotation in an opposite direction to the primary blades. The energy that would be captured by attaching blades to a segment or to the barrel which is allowed to move. As such, previously lost energy is now captured. The barrels or segments can be attached together such that the energy can be collected in a manner that can be harnessed. As such, the barrel18, as illustrated inFIGS. 1-3, can be made up of a plurality of separate segments that are interconnected together. The resulting energy can be used to power other components or directed back to the primary-driven equipment.

As can be seen inFIG. 1, the counter-rotating blades are attached to the barrel18or to an intermediate shell. This would be within the outer shell20because of pressure considerations. The energy thus harnessed could be used for powering boiler feed pumps, auxiliary pumps, hydraulics, or for generating electricity.FIG. 1further shows that the rows of blades alternate between those blades that are affixed to the main shaft and the blades that are fixed to the barrel or outer connection.

FIG. 4shows an alternative embodiment of the present invention in the form of a gas compressor40. InFIG. 4, the gas compressor40includes the main shaft42, the first set of blades43the second set of blades44, the third set of blades46and the fourth set of blades48. The first and third sets of blades will rotate in the same direction. The second and fourth sets of blades will rotate in the opposite direction. The barrel50is affixed to the second set of blades44and the fourth set of blades48. As a result, the barrel50will rotate in opposite direction to that of the main shaft42.

FIG. 4, shows, in particular, the fluid inlet52. InFIG. 4, fluid is delivered through the interior of a manifold54and directed toward the sets of blades43,44,46and48. As such, this fluid, such as a gas, will cause the respective rotation of the main shaft42and the barrel50. There is an exhaust outlet56positioned at the end of the array of blades. As such, the gas can be properly discharged. An outer shell58is provided over the exterior of the barrel50for pressure considerations. As such, the fluid can flow through the space between the outer shell58and the barrel50if the pressure should become too great.

InFIG. 4, it can be seen that the shaft42is affixed to a bearing pedestal60at one end thereof. The shaft42is connected to a power source62at an opposite end thereof. A planetary gear arrangement64is illustrated as coupling the barrel52to the shaft42. Alternatively, various other types of gearing arrangements can be provided so as to connect the rotatable barrel50.

InFIG. 4, it can be seen that the power source62can also be a pump. The addition to the power applied by the main shaft42is also supplied to the barrel50so as to drive the intermediate turbine blade stages. This results in a shorter piece of equipment and a better utilization of the power supplied by the power source.

FIG. 5shows another alternative embodiment of a gas generator70. InFIG. 5, it can be seen that the turbine apparatus70includes a first section72of the barrel74and a second section76of the barrel74. Each of the sections74and76will extend from a center section78. The center section can be a bearing and thrust support or an area in which fuel can be added to the high-pressure air flow and combusted in the secondary section. The fluid inlet can be directed through an central opening80and directed outwardly therefrom toward the blades that are attached to the barrel sections72and76. A load stage84is connected to an independent shaft82to a driving a separate unit. As such, the exhaust gas as well as the air moved by the outer blades88and90would impinge on the load stage84.

FIG. 5illustrates that the fan blades88and90that extend outwardly of the exterior surface of the barrel sections72and76. These fan blades88and90extend toward the outer shell92. The exhaust94passes outwardly of an exhaust outlet96of the turbine apparatus70. In another embodiment, the fan blades88and90can be replaced with magnets.

The turbine apparatus70causes the counter-rotating sets of blades to bring additional flow to impinge upon the load stages. This is done by adding the fan blades88and90to the barrel94and/or to the outer shell92and then directed toward the load stages. The barrel can also be used to power additional electrical generation, pumps, or miscellaneous auxiliary equipment.

FIG. 6shows another alternative embodiment100of the turbine apparatus of the present invention, in the nature of a turbofan.FIG. 6has a similar configuration to that shown inFIG. 5. However, inFIG. 6, the energy from the barrel102or from the outer shell104can have fan blades106attached to the exterior thereof so as to increase the air flow around the exterior of the turbine. The results in a smaller first set of blades108than the diameter of the second set of the fan blades110. This facilitates the movement of the air around the turbine apparatus100. The advantage of this is to decrease the frontal areas. As such, drag is also reduced. The segments of barrel102can also be used to power auxiliary needs, such as hydraulic, electricals, ventilation systems, or other miscellaneous systems.