The present invention relates generally to turbo-machinery, and more particularly to turbine-driven alternators used to convert the stored energy of a process gas into electrical energy. Such turbine-driven alternators, or turboalternators, may be used in various applications, such as compressed air energy storage (CAES), waste gas energy recovery (WGER), pressure letdown, gas liquefaction, and organic Rankine cycles (ORC).
Turbine-driven alternators, namely turboalternators, are a key piece of machinery in many different systems for generation of energy. A turbine converts stored energy in a process gas to mechanical energy. An alternator, which is typically coupled to the turbine via a rotating shaft, converts the mechanical energy into electrical energy. The electrical energy is then supplied to a load. Such a turboalternator thus provides a means for converting energy stored in a process gas into electrical energy that is readily available to the user. These devices are especially useful for self-generation of electric energy and local power, and have long been employed in circumstances where power is not readily available from traditional sources, such as in remote locations.
U.S. Pat. No. 5,045,711 describes a prior art turboexpander-generator device typical of devices used on offshore oil/gas platforms where a source of pressurized gas is available and used to generate electricity. This device utilizes a turboexpander, an electric generator, and a lubrication pump, all fixed to a common rotating shaft. The lubrication pump provides oil to bearings supporting the rotating shaft, and further controls an actuator associated with variable inlet nozzles of the turboexpander. Unfortunately, oil-lubricated bearings as used in the device of U.S. Pat. No. 5,045,711 are unreliable, especially at the high running speeds more typical of and expected from modern turbomachinery devices. Further, shaft seals tend to wear out quickly and oil contamination of the process gas becomes a significant problem.
Similar turboalternator devices have attempted to address the deficiencies of oil-lubricated bearings. For example, U.S. Pat. Nos. 4,362,020 and 4,558,228 replace oil-lubricated bearings with hydrodynamic tilting pad bearings in energy conversion turboalternator systems. Unfortunately, titling pad bearings still suffer from high power loss, mechanical complexity, pivot fretting, limited damping capacity and indirect measurement of bearing loading.
An additional common concern with turboalternator devices is the creation of a high thermal signature. Thus, an important aspect of the design of such machinery is the creation of a temperature drop across the turbine. In turn, such a temperature drop allows the device to run more efficiently. In many conventional systems, an orifice plate is used to create a temperature drop isenthalpic expansion (i.e., the Joule-Thomson effect). By replacing the orifice with a turbine, a much higher temperature drop can be achieved, and thus more efficient operation. This occurs because high-pressure gas is expanded to produce work for driving the alternator, an isentropic process where the resultant low-pressure exhaust gas can achieve desirable very low temperature levels.
To achieve high efficiency in such machinery, the turbine must run at high rotational speeds. As rotational speed increases, the overall machine size can be made smaller without compromising the alternator's output power. Heretofore, known problems with turboalternator devices arose due to the excessive size and complexity of such devices. Requirements for running at high speed include properly designed rotating and non-rotating assemblies and bearings to support a high-speed rotating shaft, which, as noted above, permits smaller devices to be used without affecting operative efficiency and power.
Relative velocities for rotating shafts in turboalternator devices are high. For example, the running speed of the rotating shaft for a two-inch diameter turbine rotor is typically 150,000 rpm. The graph in
High-speed rotating machines supported on foil air bearings have made significant progress during the last 35 years. Reliability of many high-speed rotating machines with foil bearings has shown a tenfold increase compared to those with rolling element bearings. Many high-speed rotating machines are Air Cycle Machines (ACM) used in Environmental Control Systems (ECS) of aircraft that manage cooling, heating and pressurization of the aircraft. Today, ACM for almost every new ECS system on military and civilian aircraft and on many ground vehicles use foil air bearings. Old ECS systems with rolling element bearings are being converted to foil air bearings. The F-16 aircraft ACM used rolling element bearings from 1974 to 1982, but all such aircraft built since 1982 use foil air bearings. The 747 aircraft ACM used rolling element bearings from 1970 to 1989. All such aircraft built since 1989 have foil air bearings. ECS on the older model 737 aircraft have rolling element bearings, whereas ECS on the new 737 aircraft use foil air bearings. An overview of foil air bearing technology is provided in an ASME paper (97-GT-347) by Giri L. Agrawal.
The use of foil air bearings in turbomachinery has several advantages:
Oil-Free Operation—There is no contamination with oil. The working fluid in the bearing is the system process gas which could be air or any other gas. For many systems such as gas liquefaction plants, oil-free operation is a necessity.
Higher Reliability—Foil bearing machines are more reliable because there are fewer parts to support the rotating assembly and there is no lubrication needed to feed the system. When the machine is in operation, the air/gas film between the bearing and the shaft protects the bearing foils from wear. The bearing surface is in contact with the shaft only when the machine starts and stops. During this time, a coating on the foils limits the wear.
No Scheduled Maintenance—Since there is no oil lubrication system in machines that use foil bearings, there is never a need to check and replace the lubricant. This results in lower operating cost.
Environmental & System Durability—Foil bearings can handle severe environmental conditions such as shock and vibration loading.
High Speed Operation—Turbine rotors have better aerodynamic efficiency at higher speeds. Foil bearings allow these machines to operate at the higher speeds without any limitation as with ball bearings. In fact, due to the hydrodynamic action, they have a higher load capacity as the speed increases.
Low & High Temperature Capabilities—Many oil lubricants cannot operate at very high temperatures without breaking down. At low temperature, oil lubricants can become too viscous to operate effectively. Foil bearings, however, operate efficiently at severely high temperatures, as well as at cryogenic temperatures.
The present invention provides a turbine-driven alternator, namely a turboalternator, that can be used in various applications, such as for compressed air energy storage, waste gas energy recovery, pressure letdown, gas liquefaction, and organic Rankine cycling.
In one aspect of the present invention, a turboalternator for recovering energy stored in a process gas comprises a turbine and a generating device. The turbine has a turbine housing with a process gas inlet and a process gas outlet. The generating device has a generating device housing with a power connector for outputting electrical energy. The generating device housing and the turbine housing are attached together to collectively define an interior cavity in which a rotating assembly is disposed. The rotating assembly comprises a rotating shaft mounted for rotation about an axis, a turbine wheel mounted on a first end of the rotating shaft and being disposed within the turbine housing, at least two hydrodynamic foil journal bearing assemblies mounted within the generating device for supporting the rotating shaft, at least one hydrodynamic foil thrust bearing assembly having a thrust runner mounted for rotation with the rotating shaft adjacent a second end thereof opposing the turbine wheel, and a rotor forming an armature of the generating device that is mounted for rotation with the rotating shaft. A tie rod extending along the axis of rotation holds the turbine wheel, the rotating shaft, the at least two journal bearing assemblies, the at least one thrust bearing assembly, and the rotor under preload. The turbine wheel is mounted for rotation about the axis of rotation in association with process gas passing between the turbine housing inlet and outlet, wherein rotation of the turbine wheel effects rotation of the rotating shaft. A stator is mounted in stationary relationship within the generating device housing relative to the rotor, wherein rotation of the rotor relative to the stator generates electrical energy, with the stator being operatively connected to the power connector to supply the generated electrical energy thereto.
In a preferred design and operation of a turboalternator in accordance with the present invention, a turbine wheel is adapted to drive an electric alternator or generator suitable for conversion of stored process gas energy into electrical power. The turbine wheel receives a process gas that causes the turbine wheel to rotate about an axis. The rotating shaft is supported by hydrodynamic foil journal bearings within the housing and operatively communicates with the turbine wheel and the alternator or generator to convert the process gas energy into electrical power by way of shaft work.
In another aspect of the present invention, axial load of the turboalternator may be borne by at least one hydrodynamic foil thrust bearing assembly mounted within the housing.
The present invention avoids the deficiencies of prior art devices that utilize, for example, oil-lubricated bearings or tilting pad bearings, by supporting the rotating shaft in hydrodynamic foil gas bearings. Such foil gas bearings do not require a supply of pressurized gas as with some prior art turboalternator devices. Further, such foil gas bearings overcome limitations associated with prior art devices, including high power loss, mechanical complexity, pivot fretting, limited damping capacity, indirect measurement of bearing loading, high thermal signature, fuel inefficiency, noise, vibration, increased size and weight, required scheduled maintenance, oil contamination, and higher costs. The use of foil gas bearings moreover provides the advantages of enabling running at high speeds desired for optimum turbine efficiency and machine reliability without compromising output power or without increasing machine size.
In another aspect of the present invention, a turboalternator in accordance with the present invention may be used in a power generating system wherein the turboalternator is operatively connected to an auxiliary unit for supplying a process gas to the turbine housing inlet to effect rotation of the turbine wheel. Such a power generating system has applicability in several applications and set-ups requiring conversion of a process gas into electrical energy and power readily available to the user, including the following:
Compressed Air Energy Storage (CAES) refers to the compression of air during periods of low energy demand, for use in meeting periods of higher demand. Typically, compression is done with an electrically powered turbo-compressor; and expansion is done with a natural-gas powered heater which drives a turbine driven generator. Air can be stored underground in a cavern created by solution mining (salt is dissolved away) or an abandoned mine. Plants are designed to operate on a daily cycle, charging at night and discharging during the day.
Turboexpander-Generator (also referred to as “turbo expander”, “expansion turbine” or simply “expander”) is a centrifugal or axial flow turbine through which a high-pressure gas is expanded to produce work that is used to drive a compressor or generator. Because work is extracted from the expanding high pressure gas, the expansion is isentropic and the low-pressure exhaust gas from the turbine is at a very low temperature, often as low as −300° F. or less. Turboexpanders are very widely used as sources of refrigeration in industrial processes such as: the extraction of ethane as well as natural gas liquids (NGLs) from natural gas; the liquefaction of gases; and other low-temperature processes.
Pressure Letdown Stations refers to commercial processing plants that use pressure reducing valves (PRV) to letdown the process gas (oftentimes steam) to lower pressure. An example is the production of cheese where 125 psig saturated stream is used for pasteurization, 80 psig for curd processing and <60 psig for mixing, drying and cleaning. Replacing the PRV with a turboalternator allows for recovery of otherwise wasted energy.
Waste Gas Energy Recovery (WGER) refers to the extraction of usable energy from industrial process gas that would otherwise be dumped to atmosphere. A turboalternator can be used to extract energy from low pressure gas to recover energy and improve system overall efficiency. An example of WGER is a turboalternator installed in the exhaust of an internal combustion engine used to generate electricity from the engines exhaust. A turboalternator could be used in series or parallel with a turbocharger.
Organic Rankine Cycle (ORC) refers to a system used to extract usable energy from low grade waste heat, such as industrial waste heat, geothermal heat, solar thermal power and solar ponds. These systems are used where the pressure of the waste stream is too low to be directly utilized through a turbine. depending on the temperature of the heat source, many different process fluids are used, such as pentane, butane, R-134a, R-245fa, etc.
These and other features of the present invention are described with reference to the drawings of preferred embodiments of a turbo-driven alternator device, its components, and various applications for such device. The illustrated embodiments of the turbine-driven alternator device of the present invention are intended to illustrate, but not limit features of the invention.
The present invention is directed to a power generating system for recovering energy stored in a process gas. A perspective view and cross-section of an exemplary turbine-driven alternator in accordance with the present invention, generally designated by reference numeral 10 and hereinafter referred to as “turboalternator 10”, are illustrated in
The turboalternator 10 generally comprises a turbine 12 and a generating device 14, such as an alternator or a generator. In general, the turboalternator of the present invention operates the same regardless of whether the generating device is an alternator or a generator. Hereinafter, the generating device 14 is described with reference to a generator. However, this description equally applies to a device using an alternator as the generating device 14.
The turbine 12 includes a turbine housing 16 defining an interior space within which a turbine wheel or rotor 18 is rotatably mounted. A process gas enters the turbine 12 through an inlet 20, is directed through a fixed inlet nozzle 22 (
Upon rotation of the turbine wheel 18, the turbine 12 converts mechanical energy to shaft work, which, in turn, is converted to electric power by the generator 14 of the turboalternator 10. The electrical energy or power is withdrawn from the generator 14 through a power connector 26 provided on a generator housing 28. The electrical outlet of the power connector 26 may provide power to any desirable machinery, power storage unit or the like. Generally, the power output is AC power. In the event that a DC output is desired, power can pass through additional power electronics, not shown but generally known to the person of ordinary skill in the art.
As shown in
An insulator plate 32 is fixed between the turbine housing 16 and the generator housing 28. This insulator plate 32 minimizes heat transfer between the turbine side and the generator side of the turboalternator 10. Such insulation prevents components from overheating, controls the thermal signature of the device, and therefore improves the overall efficiency of the turboalternator 10.
In operation of the turboalternator 10 of the present invention, the rotating assembly 34 is preferably driven by rotation of the turbine wheel 18 about the axis of rotation. Shaft rotation, generally in the range of 60,000 to 80,000 rpm, effects operation of the generator 14. Preferably, the generator 14 is a permanent magnet generator comprising a generator rotor 46 and a generator stator 48 relatively positioned with respect to one another to generating electrical energy upon rotation of the generator rotor 46 with respect to the stationary generator stator 48. More specifically, the generator rotor 46 is mounted on the rotating shaft 36 at an intermediate position between the opposing ends of the rotating assembly 34, generally between the journal bearing assemblies 42. In a preferred design, the generator rotor 46 includes a permanent magnet 50 and a non-magnetic retaining sleeve 52. The retaining sleeve 52 may include a metallic cylinder press fit over the magnet 50 with end caps to protect the magnet 50. Alternatively, the retaining sleeve 52 may take the form of non-metallic fiber wound around the magnet 50. As so situated and designed, the generator rotor 46 acts as the generator's armature for driving the rotating assembly 34. The generator stator 48 is supported in the generator housing 28 around the generator rotor 46, with coils (not shown) encircling the generator rotor 46 to operatively interact with the permanent magnet 50.
Referring to
Referring to
Typically, the thrust runner 40 has first and second opposed axial sides, which act as thrust carrying surfaces. In a preferred design, at least one thrust bearing 64 is provided on a respective axial side of the thrust runner 40. Each thrust bearing 64 includes a thrust bearing plate 66 with multiple top foils 68 disposed thereon, and a spring plate 70 with multiple leaf springs or flat springs 72 disposed thereon. An additional resilient plate 74 is provided outwardly adjacent to each spring plate 70 and includes additionally spring elements 76 to provide added resiliency to the thrust bearing assembly 38.
In operation, each thrust bearing plate 66, spring plate 70, and resilient plate 74 are preferably kept stationary within the bearing housing portion 58 of the generator housing 28 relative to the thrust runner 40 to aid in distribution of axial loads. Thus, the thrust bearing assembly 38 supports and transmits the axial load of the rotating assembly 34 through the entire assembly in a distributed fashion. In order to further meet high load capacity requirements of a rotating machine, such as turboalternator 10, two or more thrust bearing assemblies may be used to share the loads.
Referring to
A first open or split, generally cylindrical-shaped, smooth foil element 84 is disposed with the annular spacing 80 and is fixed along an edge to a side of a key 86 slidably received within the keyway 82. A second open or split, generally cylindrical-shaped, smooth foil element 88 is provided inwardly of, concentric to, and overlapping the first foil element 84 within the annular spacing 80. An end portion of the second foil element 88 is disposed within the keyway 82. A corrugated resilient backing member or spring 90 is disposed within the annular spacing 80 between the retaining member and the foil elements 84, 88. An end portion of the spring 90 is also disposed within the keyway 82.
The journal bearing assembly 42 operates under the basic principle of generation of hydrodynamic pressure in the portion of the annular spacing 80 between the rotating shaft 36 and the foil elements 84 and 88. During starting and stopping of rotation of the rotating shaft 36, the second foil element 88 often rubs against the rotating shaft 36 until a fluid film is created. As the rotating shaft 36 rotates, regions of high pressure and low-pressure between the rotating shaft 36 and the foil elements 84 and 88 are established and maintained, and fluid flows from a high-pressure zone to a low-pressure zone resulting in a squeezing of the fluid between the rotating shaft 36 and the foil elements 84 and 88. This phenomenon defines supporting fluid film that supports radial loads on the journal bearing assembly 42 and prevents the rotating shaft 36 from contacting the foil elements 84 and 88. Moreover, enhanced coulomb damping is achieved in the journal bearing assembly 42 by a rubbing of the second foil element 88 against the first foil element 84, and the first foil element 84 against the spring 90, with the general movement of the foil elements 84 and 88 and the spring 90 being in opposite directions within the annular spacing 80 to the adjacent element so as to achieve greater energy dissipation and damping than movement of the foil elements in the same direction.
As shown in
The turboalternator of the present invention also provides for self-cooling of its operating components. As shown in
The amount of process gas leakage permitted into the generator housing 28 can be regulated by a seal 98 disposed between the turbine housing 16 and the generator housing 28. The seal 98 is preferably a labyrinth seal that is sized to minimize axial thrust and balance thrust load, while providing a metered amount of cooling gas to flow through the generator housing along the path marked by the arrows in
Various cooling media can be used to cool the generator stator 48. Typically, the cooling medium selected depends on the specific application. In an organic Rankine cycle, for example, liquid refrigerant or water may be used to cool the system. The liquid can be provided to the turboalternator from an external cooling liquid supply (not shown). In a CAES system, compressed inlet air may be used to cool the generator stator 48 before entering the turbine housing 16, thereby increasing the turbine inlet temperature and further increasing the overall efficiency of the system. In such a system, a coolant medium is introduced to the generator housing 28 through a cooling inlet (e.g., through inlet 99 shown in
Though the turboalternator of the present invention is shown as a single stage turbine-driven device, the present invention may also utilize a two-stage turbine-driven device without deviating from the focus of the present invention. Moreover, such two-stage devices may use one stage on either end of the rotating assembly, or multiple stages on one end of the rotating assembly.
As shown in
The foregoing description of embodiments of the invention has been presented for the purpose of illustration and description, it is not intended to be exhaustive or to limit the invention to the form disclosed. Obvious modifications and variations are possible in light of the above disclosure. The embodiments described were chosen to best illustrate the principals of the invention and practical applications thereof to enable one of ordinary skill in the art to utilize the invention in various embodiments and with various modifications as suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto.
This application claims the benefit of U.S. Provisional Application No. 60/898,896, filed Feb. 1, 2007, which is incorporated herein by reference.
Number | Date | Country | |
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60898896 | Feb 2007 | US |