The present invention relates to the field of power plants. More particularly, the invention relates to turbine shaft bearing apparatus that supports a turbine of a novel configuration to help in increasing the total power output of a single turbine module.
Due to the worldwide environmental considerations particularly relating to use of energy resources, it has become, recently more important to utilize relatively medium to low temperature heat sources or resources, such as geothermal steam and/or geothermal brine as well as industrial waste heat, for power production.
An Organic Rankine Cycle (ORC) is well suited to exploit the energy content of a medium to low temperature heat source or resource due to the relatively low boiling point of organic motive fluid. Organic fluid flowing in a closed cycle vaporizes after extracting heat from the medium to low temperature heat source or resource. The vapor is expanded in an organic vapor turbine that converts heat in the vapor to work and produces heat-depleted or expanded organic vapor that is condensed in a condenser. The condensed organic fluid is returned to the vaporizer, and the cycle is repeated.
An important consideration in designing the power capacity of such a power plant is the selection of a suitable turbine configuration. Reliable operation of the turbine is contingent upon the structural strength of the shaft that enables turbine rotor rotation and upon the ability of the bearings that support the turbine shaft to absorb both the radial load and axial thrust imposed by the expansion of the motive fluid within the turbine.
One prior art bearing arrangement for supporting a rotating turbine shaft is an overhang design illustrated in
It is to be noted that the maximum number of turbine wheels that can be supported by the overhang bearing arrangement is usually limited to three as a result of the bending stress, significantly reducing the power output of a turbine from what could be achieved if more turbine wheels could be incorporated therewith.
Another disadvantage of the overhang bearing arrangement is that the end of the turbine shaft that is unsupported by the bearings can undergo an induced vibration phenomena, particularly flexural vibration. Such vibration can result in damage to elements with small radial clearance such as seals.
WO 2013/171685 discloses an ORC system that comprises a radial turbine of the axial inflow and radial outflow type. The turbine is formed by a single rotor disc that carries rotor blades to define a plurality of stages and that is provided with an auxiliary opening between two successive radially spaced stages. The auxiliary opening is interposed between an inlet and an outlet of the turbine, and is in fluid connection with an auxiliary cogeneration circuit so as to extract from the turbine or inject into it organic working fluid at an intermediate pressure between an injection pressure and a discharge pressure. The rotor disc is supported in a casing by two bearings, and is mounted at an end of the shaft that is cantilevered with respect to the casing according to an overhang design.
Since the vapors expand radially outwardly from the turbine shaft in this prior art configuration, large mechanical loads are imposed on the turbine shaft and on the bearings. The various radially spaced stages of the single rotor disc are very closely fitted to the stator blades, and are therefore very sensitive to expansion and contraction forces, particularly due to the application of radial forces to the stages. The applied radial forces increase for the second and third stages, which are more distant from the turbine shaft than the first stage.
Other disadvantages of this single turbine wheel configuration relate to the need of accommodating the large-sized and heavy rotor that has a correspondingly high moment of inertia, requiring an increased torque to drive the rotor, and also to the pressure losses of the vapor exiting the turbine via a 90-degree turn through a volute.
Another prior art bearing arrangement for supporting a turbine shaft is the rotor between bearings design where two bearings are axially spaced. Although the level of bending stress and vibrations is significantly reduced relative to the overhang bearing arrangement by virtue of the axially spaced bearings, one or both of the bearings may be exposed to the hot and pressurized motive fluid vapors. Due to the exposure to the hot vapors, the metal temperature of a turbine shaft bearing is liable to become excessive. As a result of bearing overheating, metal or alloy based lining having good lubricating properties tends to become weakened and shears in the direction of shaft rotation. Without protection for the metal or alloy lining, the bearing surface geometry can become altered due to the metal-to-metal contact between the bearing and the shaft, ultimately leading to possible bearing failure and an unsupported turbine shaft. At times, the sheared metal or alloy blocks the oil inlet to the bearing, resulting in another cause of bearing failure.
In addition, the rotor between bearings design has been utilized only with respect to steam turbines. Thermal stress present in steam turbines is not similar to the thermal stress that may be present in organic vapor turbines.
It is an object of the present invention to provide turbine shaft bearing apparatus for use in a rotor between bearings design that is not subject to overheating.
It is an additional object of the present invention to provide turbine shaft bearing apparatus to facilitate an increase of the total power output of the turbine and of a power plant in which the turbine is incorporated.
It is an additional object of the present invention to provide a turbine module apparatus to facilitate an increase of the total power output of the turbine and of a power plant in which the turbine is incorporated.
It is an additional object of the present invention to provide turbine shaft bearing apparatus to facilitate efficient utilization of relatively low temperature heat sources or resources.
Other objects and advantages of the invention will become apparent as the description proceeds.
The present invention provides a turbine shaft bearing apparatus, comprising two axially spaced, inlet side and outlet side bearings for providing support to a turbine shaft to which are connected a plurality of turbine wheels such that said turbine shaft, said two spaced bearings, and said plurality of turbine wheels are all coaxial, wherein said outlet side bearing is protected from overheating by motive fluid expanded by one or more of said plurality of turbine wheels or stages by a solid bearing housing which surrounds said outlet side bearing which is supported and provided with a conduit through which a lubricating medium for lubricating said outlet side bearing is supplied from a port external to said turbine.
The present invention is also directed to a single turbine module, comprising a plurality of axially spaced turbine wheels, each of which constitutes one expansion stage of said turbine module, being connected to a common turbine shaft and coaxial therewith; an inlet through which motive fluid vapor is introduced to a first stage of said turbine wheels; a structured bleeding exit opening formed in an outer turbine casing of said turbine module; and a passage defined between two of said turbine wheels and in fluid communication with said bleeding exit opening, wherein expanded motive fluid vapor is extracted through said structured bleeding exit opening and is supplied to a heat exchange component, for heating the motive fluid condensate.
The present invention is also directed to a power enhanced Organic Rankine Cycle (ORC) based power plant, comprising an organic vapor turbine adapted for interstage bleeding of organic motive fluid; a direct recuperator to which interstage-bled motive fluid is extracted and wherein said interstage-bled motive fluid is brought into direct contact with liquid condensate of the motive fluid; and a vaporizer for vaporizing said directly recuperated motive fluid so that vaporized motive fluid is supplied to said turbine.
In the drawings:
Turbine 10 can advantageously actually be considered of an axial flow type. Motive fluid vapor is introduced via radial inlet 12 into vapor chest 14 which provides an efficient inlet for the turbine, and is axially discharged to turbine wheels 18A-D via vapor chest exit 16. The rotatable turbine wheels 18A-D, fixed and connected to turbine shaft 15, by e. g. a ring fedder connection, are provided in a chamber defined by the radial space between turbine shaft 15 and annular turbine housing 13, which is axially adjacent to vapor chest 14 and radially adjoining outer turbine casing 19. Herein, four turbine wheels and their use is described and shown but, if desired, according to the present invention, another number of turbine wheels can be used.
Each of the turbine wheels 18A-D comprises one expansion stage of turbine 10. The rotatable blades carried by a turbine wheel of a given stage interact with a corresponding set of fixed blades that are attached to turbine housing 13 and are arranged as a ring, often referred to as a nozzle ring 26 so that the fixed blades or openings act as nozzles. The motive fluid is introduced to nozzle ring 26, which causes a partial decrease in pressure and a partial increase in velocity of the motive fluid. The stream of increased-velocity motive fluid is directed onto the corresponding rotating blades of the given expansion stage to utilize the kinetic energy of the motive fluid.
This process is carried out for each expansion stage, so that the motive fluid is increasingly expanded by the blades carried by each of turbine wheels 18A-D, such that the expanded vapor exiting the last stage turbine wheel 18D flows through expanded vapor chamber 21, located downstream to the turbine wheels. Expanded vapor chamber 21 is coincident with convergent outer cone 23 extending from turbine casing 19, and the expanded motive fluid exits turbine 10 via outlet 24, which is axially spaced from inlet 12. The expanded motive fluid vapor exiting outlet 24 is directed to the condenser of the power plant or to a heat exchange component in fluid communication therewith.
This axial inflow and outflow configuration facilitates axial expansion, so that the vapor-derived forces applied to turbine shaft 15 are substantially evenly distributed. Turbine shaft 15, which is usually coupled to an electric generator, is consequently caused to rotate by these vapor-derived expansion forces and to generate electric power.
In turbine 10, turbine shaft 15 is properly positioned and rotatably supported by two axially spaced bearings 17 and 27 in accordance with a rotor between bearings design, such that turbine shaft 15, bearings 17 and 27, and turbine wheels 18A-D are all coaxial, as also shown in
As a result of the axial flow of the motive fluid produced within vapor chest 14 and thereafter to turbine wheels 18A-D, inlet-side bearing 17 is not exposed to the high temperature of the motive fluid, and therefore may be of conventional configuration, for example a spherical roller bearing adapted to handle a combined load associated with both a load imposed by the pressure differential applied by the motive fluid vapor between inlet 12 and outlet 24 and another load associated with the weight applied of the rotating turbine shaft 15. Alternatively, inlet side bearing 17 may also be a bearing based on ball bearings. Outlet side bearing 27 located proximate to expanded vapor chamber 21, however, is liable to be exposed to the relatively high temperature of the expanded motive fluid, and would be subject to overheating if it were not protected.
In the bearing apparatus of the present invention, outlet side bearing 27 is encased within a solid protective cartridge or bearing housing 29 in order to be isolated from the expanded motive fluid. Bearing housing 29 encompasses outlet-side bearing 27. Bearing housing 29 also provides sufficient cooling and lubrication of outlet-side bearing 27, so as to prevent the latter from overheating if contacted or otherwise exposed to the hot expanded motive fluid.
A seal 31 is also positioned within bearing housing 29 to protect outlet-side bearing 27 from being impinged by hot unexpanded motive fluid, resulting for example from passage radially inwardly along the turbine wheels and axially along turbine shaft 15. Seal 31 is in sealing engagement with both the turbine shaft and the outlet-side bearing facing turbine shaft 11, to prevent ingress thereto of the hot motive fluid.
Exemplary bearing types that may be used for outlet side bearing 27 include a carb bearing and a cylindrical roller bearing in order to support the turbine shaft despite any thermal expansion of the turbine shaft that may take place. Roller bearings are particularly suitable for use with an organic motive fluid by virtue of their resistance to frictional losses.
Turbine 10 may be configured with an inner convergent cone 34 within an inner region of expanded vapor chamber 21, to provide additional means for isolating outlet side bearing 27 from the expanded motive fluid and for guiding the expanded motive fluid towards outlet 24. Inner cone 34 extends from an intermediate region of radially extending partition 37, which is positioned at the downstream side of final stage turbine wheel 18D and connected to turbine housing 13, to support element 38 located proximate to the turbine's longitudinal axis 11 and adjacent to outlet 24.
In the illustrated configuration, six evenly spaced bearing supports 41 are provided, with an angular interval of 60° between each bearing support. It will be appreciated that any other number of symmetrical bearing supports 41, i.e. two or more, may also be used.
With bearing 27 being contained within closed bearing housing 29, and therefore not being accessible to a separate supply of lubrication, one or more bearing supports 41 are bored to provide the supply of cooling fluid.
A first bearing support 41 is bored with an inlet 47 through which cooling fluid, e.g. lubrication oil, is injected through the wall of bearing housing 29 to the surface of outlet-side bearing 27. A second bearing support, which may be adjacent to the first bearing support, is provided with a bore 48 from which the spent cooling fluid, e.g. lubricating oil, is extracted from bearing 27. A third bearing support is formed with a bore 49 through which cooled motive fluid, e.g. supplied with motive fluid condensate, is injected to further cool the outlet side bearing 27. As bearing 27 normally undergoes an increase in temperature due to friction during rotation of the turbine shaft, the injected motive fluid evaporates shortly after contacting the bearing surface of increased temperature and consequently brings about the cooling of the bearing as well as seal 31. Furthermore, the pressure of the cooling fluid, e.g. thermal oil, can be adjusted to control the axial force applied by the turbine shaft.
As shown in
Referring now to
Alternatively, the turbine casing may be configured with a radial split design to facilitate access to the turbine shaft and to the turbine wheels via the radial split whenever needed.
Although the description relates to a turbine of the axial flow type, i.e. axial inflow and outflow, it will be appreciated that the teachings of the present invention are also applicable to other types of turbines, such as the radial inflow type or the radial outflow type.
As was previously explained, the rotor between bearings design allows an additional turbine wheel or wheels to be mounted to the turbine shaft by virtue of the increased tensile strength of the turbine shaft. In addition to providing an increase in the total power output of the turbine, the added turbine wheel facilitates, if desired, interstage bleeding.
The flow capacity of the motive fluid extracted by interstage bleeding is controlled by the pressure differential of the motive fluid pressure at bleeding exit 67 and at the heat exchange component, and also by the target temperature of the motive fluid to be achieved at the heat exchange component and the amount of heat to be extracted from the bled motive fluid at the heat exchange component. The target temperature determines the amount of motive fluid related heat to be extracted via bleeding exit 67.
The remaining portion of the expanded motive fluid vapors, usually expanded motive fluid vapors, not extracted via passage 63 and bleeding exit 67 is fed to the nozzle ring of the subsequent turbine wheel stage, after flowing across passage 63. The rate of feeding from one stage to another is determined by the pressure difference between adjacent expansion stages, while taking into consideration the bleeding motive fluid flow as well.
Although interstage bleeding is known from the prior art, such as U.S. Pat. No. 7,797,940, a Continuation-in part case of U.S. Pat. No. 7,775,045, the disclosures of which are hereby incorporated by reference, the prior art interstage bleeding is carried out only with respect to only up to three turbine wheels known in the prior art, while turbine 60 of the present invention is able to facilitate interstage bleeding with the use of at least four turbine wheels. Turbine 60 is therefore able to produce higher power levels by virtue of the four turbine wheels as a result of the larger difference between vaporizer and condenser pressure that is able to be achieved due to a relatively high enthalpy difference, and the power plant in which turbine 60 is incorporated is able to realize an increased thermal efficiency.
The use of a recuperator is suited for an ORC since the cycled organic motive fluid expands in turbine 60 in a dry superheated regime and the recuperator permits the recovery of the heat contained in the superheated vapor exiting the turbine or extracted from the turbine by utilizing this heat within in the ORC cycle. In power plant 70, the heat content of the expanded organic vapor is optimally utilized by advantageously employing both a direct recuperator 81 and an indirect recuperator 84.
The completely expanded organic motive fluid exhausted from the last stage turbine wheel of turbine 60, after work has been performed, is delivered via conduit 76 to indirect recuperator 84. The organic vapor exits indirect recuperator 84 via conduit 77 and is delivered to condenser 87 which may be air-cooled or water cooled and which condenses the vapor by means of a cooling fluid (not shown). The condensed motive fluid is supplied by condensate pump 89 via conduit 78 to indirect recuperator 84, which is adapted to transfer heat from the turbine exhaust to the condensed motive fluid or motive fluid condensate, and then via conduit 79 to direct recuperator 81.
The interstage-bled motive fluid vapor is extracted via conduit 74 to direct recuperator 81, and is brought in direct contact with the liquid motive fluid condensate that has exited indirect recuperator 84. Direct recuperator 81 may be configured in several ways, for example as a spray whereby the motive fluid condensate is sprayed into the interior space of direct recuperator 81 to contact the interstage-bled motive fluid vapor introduced therein. The interstage-bled motive fluid vapor is caused to condense following contact with the lower temperature liquid condensate droplets, which provide a relatively large heat transfer surface area. Latent heat of the interstage-bled motive fluid vapor is released during condensation and heats the motive fluid liquid condensate.
The further heated condensate produced exiting direct recuperator 81 is pressurized by feed pump 66, and is delivered via conduit 73 to preheater 64 and then via conduit 72 to vaporizer 62. Vaporizer 62 vaporizes the preheated motive fluid, and the motive fluid vapor is supplied to organic vapor turbine 60 via conduit 71, and specifically to the nozzle ring of the first turbine wheel stage.
In this fashion, a significant increase in heat influx is provided to the motive fluid by thermal energy, despite the extraction of heat at an intermediate stage of the turbine and despite the relatively low pressure differential between the interstage-bled motive fluid vapor and the recuperated motive fluid liquid. As a consequence, an increased level of power output can be extracted from the turbine.
A suitable heat source fluid, such as geothermal fluid e.g. geothermal steam or geothermal brine or waste heat, etc., is introduced to vaporizer 62 and is brought in heat exchanger relation with the preheated motive fluid in order to vaporize the latter. The heat-depleted heat source fluid exits vaporizer 62 via conduit 58 and is supplied to preheater 64, and preheats the motive fluid liquid supplied by feed pump 66. When the heat source fluid is geothermal fluid, it flows in an open cycle and is advantageously re-injected into an injection well via conduit 59 after exiting preheater 64. For some heat source fluids such as heat transfer fluid e.g. thermal oil, the heat source fluid recirculates within a closed cycle.
The use of direct recuperator 81 is of particular benefit when the heat source fluid is geothermal fluid, e.g. brine, since at times it is preferred that additional heat should not be extracted from the heat source. The additional heat influx provided by direct recuperator 81 thus provides compensation as far as heat is concerned.
It is to be pointed out that while recuperator 81 is described as a direct recuperator in which direct contact is made between the organic motive fluid vapor bled from passage 63 and the organic motive fluid condensate supplied from indirect recuperator 84, advantageously, recuperator 81 can be an indirect recuperator so that heat contained in heat contained in the organic motive fluid vapor bleed can be indirectly transferred to organic motive fluid condensate supplied from indirect recuperator 84.
Power plant 90 is similar to power plant 70 of
In this embodiment, power plant 110 comprises two independent closed ORC loops, a high temperature cycle 105 and a low temperature cycle 115. Both the turbine of high temperature cycle 105 and the turbine of low temperature cycle 115 may be coupled to a common generator for producing electricity.
High temperature cycle 105 is similar to power plant 70 of
Low temperature cycle 115 comprises organic vapor turbine 121 not utilizing interstage-bleeding, condenser 127 for receiving the expanded motive fluid vapor exhausted from the last stage of turbine 121 via conduit 111 and for condensing the same by a suitable cooling medium (e.g. air or water), condensate pump 129 for supplying the condensate via conduit 114 to preheater 131 and to which a low temperature heat source fluid is supplied in order to increase the temperature of the condensate received from pump 129, and vaporizer 133 for vaporizing the preheated motive fluid flowing thereto via conduit 116. The low temperature motive fluid vapor produced is supplied to turbine 121 via conduit 118.
The heat-depleted high temperature heat source fluid exiting vaporizer 62 of high temperature cycle 105 flows via conduit 58 to preheater 64, and preheats the motive fluid liquid supplied from direct recuperator 81 by feed pump 66. The heat depleted high temperature heat source fluid exiting preheater 64 is supplied through conduit 109 to vaporizer 133 of low temperature cycle 115. Even though the high temperature heat source fluid is additionally heat-depleted, its heat content is sufficiently high to vaporize the preheated low temperature motive fluid liquid.
Referring to
stage organic motive fluid turbine, if desired, the present invention and is embodiments can be practiced wherein less expansion stages are used in the multi-stage turbine.
Line 145 represents the heat influx to the motive fluid in response to flowing through the indirect recuperator 84, while the direct recuperation or bleeding process is shown in a further segment (designated 143), after the motive fluid vapor having been expanded in the turbine, extracted and condensed. Consequently, the injection of the directly recuperated motive fluid into the preheater of the high temperature cycle obviates the need of having to exploit a substantial amount of heat from the heat source fluid in the high temperature cycle. Thus, the heat content of the heat source fluid exiting the preheater remains sufficiently high to enable its use in the low temperature cycle.
In
While the description of the present invention refers to interstage bleeding of motive fluid vapor, in accordance with present invention, injection of motive fluid, such as organic motive fluid, can be used in the multi-stage turbine of the present invention.
Furthermore, while the present description of the present invention and its embodiments refers to a multi-stage turbine, e.g. a four-stage expansion turbine, the present invention and its embodiments can be practiced in a turbine having less than four stages. In addition, the present invention and its embodiments can also be practiced in a turbine having more than four stages
While some embodiments of the invention have been described by way of illustration, it will be apparent that the invention can be carried out with many modifications, variations and adaptations, and with the use of numerous equivalents or alternative solutions that are within the scope of persons skilled in the art, without exceeding the scope of the claims.
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