RADIAL CENTRIFUGAL TURBOMACHINE

Abstract

A radial centrifugal turbomachine with an adjusting device operatively active at the axial inlet of the turbomachine fixed casing, including: an annular member delimiting at least one radially inner passage at the axial inlet, wherein the member front surface and abutment surface of the casing delimit a radial annular passage. An actuator is connected to the member and to move axially and/or rotate according to a predefined angle to vary the radial annular passage and/or passage sections delimited between stator blades of the turbomachine first radial stage. A transmission shaft coaxial with the rotation axis and integral with the member is operatively connected to the actuator. The adjusting device allows adjusting the mass flow rate at the inlet to better adapt the performances of the turbomachine to the loading of the process/cycle and to implement a safety system dedicated to stopping the turbomachine in case of an urgent stop request.

Claims

1-18. (canceled)

19. A radial centrifugal turbomachine, comprising: a fixed casing; a rotor disc installed in the casing and rotatable in the casing around a respective rotation axis; a ring of rotor blades mounted on a front face of the rotor disc and coaxial with the rotation axis, in which the rotor blades project axially from the front face of the rotor disc; a ring of stator blades, radially inner and concentric with respect to the ring of rotor blades, in which the stator blades extend axially between the casing and the front face of the rotor disc, in which the stator blades delimit between them passage sections; wherein the casing has an axial inlet that is radially inner with respect to the ring of stator blades; an adjusting device operatively active at the axial inlet; in which the adjusting device comprises: an annular member delimiting at least one radially inner passage for the fluid, the annular member being located at the axial inlet, in which a front surface of the annular member and an abutment surface of the casing delimit between them a radial annular passage; at least one actuator connected to the annular member and configured to move axially and/or to rotate around the rotation axis, according to a predefined angle, the annular member so as to vary the radial annular passage and/or the passage sections; a transmission shaft coaxial with the rotation axis, integral with the annular member and operatively connected to the actuator.

20. The turbomachine of claim 19, wherein the annular member is movable both in rotation and axially upon command of an axial and rotation actuator.

21. The turbomachine of claim 19, wherein the annular member is movable axially up to a closed configuration for blocking the flow of fluid through the turbomachine, wherein, in the closed configuration, the front surface of the annular member lies against the abutment surface of the casing and the radial annular passage is closed.

22. The turbomachine of claim 21, wherein the annular member is movable between a configuration a) of complete opening of the radial annular passage, in which the front surface of the annular member lies at a maximum distance from the abutment surface of the casing, and the closed configuration b).

23. The turbomachine of claim 22, wherein the annular member can be stopped in any intermediate position c) between the configuration a) of complete opening and the closed configuration b).

24. The turbomachine of claim 21, wherein the adjusting device incorporates a safety device configured to bring the annular member into the closed configuration in case of emergency.

25. The turbomachine of claim 24, wherein the safety device comprises elastic means configured to push the annular member towards the abutment surface and into the closed configuration; wherein the actuator acts axially in opposition to the elastic means.

26. The turbomachine of claim 25, wherein the elastic means are pre-loaded.

27. The turbomachine of claim 25, wherein the actuator is single-acting and moves the annular member away from the abutment surface of the casing and towards the configuration of complete opening, opposing the elastic means.

28. The turbomachine of claim 25, wherein the elastic means are configured to bring the annular member into the closed configuration in a closing time comprised between 0.02 s and 0.1 s.

29. The turbomachine of claim 19, wherein the annular member has a diverging surface that delimits the radially inner passage.

30. The turbomachine of claim 19, wherein the adjusting device comprises radial elements which connect the annular member to the transmission shaft.

31. The turbomachine of claim 19, wherein the adjusting device comprises a guide element integral with the casing, coaxial with the rotation axis and slidably engaged with the transmission shaft.

32. The turbomachine of claim 31, wherein the guide element is engaged with a distal end of the transmission shaft, in which between the shaft and the guide element, a small chamber with variable volume is delimited, in which the guide element and/or the shaft have vent channels in fluid communication with the small chamber with variable volume.

33. The turbomachine of claim 19, wherein the annular member has a plurality of through slits, in which each of the stator blades is inserted in and slidably coupled with one of the through slits, in which the axial movement of the annular member involves a height variation of the stator blades and of the passage sections between the stator blades.

34. The turbomachine of claim 19, wherein the annular member can be rotated around the rotation axis according to a predefined angle upon command of the actuator; wherein each of the stator blades can be oriented around a respective adjustment axis parallel to the rotation axis and is operatively connected to the annular member; wherein a rotation of the annular member involves a synchronized orientation of the stator blades around the respective adjustment axes and a variation of the passage sections delimited between the stator blades.

35. The turbomachine of claim 19, wherein the adjusting device comprises a transmission ring coaxial with the rotation axis and radially outer with respect to the radially inner passage of the annular member; wherein the transmission ring is axially fixed with respect to the casing and is movable in rotation with respect to the casing together with the annular member; wherein the transmission ring is connected to each of the stator blades at points spaced from the respective adjustment axes.

36. The turbomachine of claim 19, wherein the casing comprises an inlet duct mounted on the axial inlet, wherein the transmission shaft is at least partly housed within the inlet duct, wherein the axial actuator and/or the rotation actuator are connected to the transmission shaft at a proximal end, opposite the distal end of the transmission shaft, which exits outward from the inlet duct.

Description

DESCRIPTION OF THE DRAWINGS

[0042] Such description will be set forth hereinbelow with reference to the enclosed drawings, provided only as a non-limiting example, in which:

[0043] FIG. 1 illustrates a meridian section of a first embodiment of a radial turbomachine in accordance with the present invention;

[0044] FIG. 1A shows a front section of an enlarged portion of the turbomachine of FIG. 1;

[0045] FIG. 1B shows an optional element of the turbomachine of FIG. 1;

[0046] FIG. 2 illustrates a meridian section of a second embodiment of a turbomachine in accordance with the present invention;

[0047] FIG. 3 illustrates a meridian section of a third embodiment of a turbomachine in accordance with the present invention; and

[0048] FIG. 4 illustrates a meridian section of a fourth embodiment of a turbomachine in accordance with the present invention.

DETAILED DESCRIPTION

[0049] With reference to the abovementioned figures, reference number 1 overall indicates a radial centrifugal turbomachine or outflow turbomachine in accordance with the present invention. The turbomachine 1 illustrated in FIG. 1 is an expansion turbine with a single rotor disc 2. For example, such turbine 1 is employed in the field of plants for the generation of electrical energy of ORC (Organic Rankine Cycle) cycle type which exploit the geothermal resources as sources.

[0050] With reference to FIG. 1, the rotor disc 2 is provided with a plurality of rotor blades 3, 3 arranged in series of concentric rings on a respective front face 4. Each series of rotor blades 3, 3 is part of a rotor stage of the turbine 1. The rotor disc 2 is rigidly connected to a shaft 5 which is extended along a rotation axis X-X. The shaft 5 is in turn connected to a generator (not illustrated). The rotor blades 3, 3 are extended away from the front face 4 of the rotor disc 2 with leading edges thereof substantially parallel to the rotation axis X-X. The rotor disc 2 and the shaft 5 are housed in a fixed casing 6 and supported thereby such to be able to freely rotate around the rotation axis X-X.

[0051] The fixed casing 6 comprises a front wall 7, placed in front of the front face 4 of the rotor disc 2, and a rear wall 8, situated in front of a rear face 9 of the rotor disc 2 opposite the front face 4. A sleeve 10 is integral with the rear wall 8 and rotatably houses the shaft 5 by means of the interposition of suitable bearings 11. The front wall 7 has an opening defining an axial inlet 12 for a work fluid. Such axial inlet 12 is situated at the rotation axis X-X and is circular and concentric with respect to the same axis X-X.

[0052] The fixed casing 6 also houses a plurality of stator blades 13, 13 arranged in series of concentric rings and directed towards the front face 4 of the rotor disc 2. The series of stator blades 13, 13 are radially alternated with the series of rotor blades 3, 3 to define a radial expansion path of the work fluid which enters through the axial inlet 12 and expands, moving radially away towards the periphery of the rotor disc 2. In particular, the series of stator blades 13, 13 and the series of rotor blades 3, 3 are housed in an expansion volume 14. The expansion volume 14 has a radially inner annular inlet opening 15 in fluid communication with the axial inlet 12 and a radially outer annular outlet opening 16. Pairs of rings of stator blades 13, 13 and rings of rotor blades 3, 3 form radial stages of the turbine 1. In the illustrated example, the turbine 1 has two radial stages.

[0053] In the illustrated embodiment in FIG. 1, the turbine 1 also comprises an auxiliary axial stage comprising a plurality of auxiliary rotor blades 17 mounted on a peripheral edge 18 of the rotor disc 2 and extended radially away from said peripheral edge 18. A plurality of auxiliary stator blades 19 is mounted fixed on an internal wall 20 of the fixed casing 6 and said auxiliary stator blades 19 radially project towards the interior of the casing 6. Downstream of the radially outer annular outlet opening 16, a passage 21 is situated that conveys the fluid towards the auxiliary axial stage 17, 19. Downstream of the auxiliary axial stage 17, 19, a diffuser 22 is placed in fluid communication with an exhaust of the turbine 1.

[0054] The turbine 1 comprises a support disc 23 integral with the casing 6 and mounted in front of a radially more internal portion of the front face 4 of the rotor disc 2 lacking rotor blades 3. The support disc 23 lies facing the axial inlet 12 and bears, at a radially peripheral portion 24 thereof, the stator blades 13 of a first radial stage 3, 13, that closest to the axial inlet 12. Such stator blades 13 of the first radial stage 3, 13 extend axially between the support disc 23 and the front wall 7 of the casing 6.

[0055] At the axial inlet 12, an adjusting device 25 is operatively active, configured for controlling the mass flow rate of the entering fluid and for quickly blocking the entrance of fluid into the turbine 1 in case of emergency.

[0056] The adjusting device 25 of FIG. 1 comprises an annular member 26 coaxial with the rotation axis X-X. The annular member 26 is housed in the casing 6 immediately downstream of the opening defining the axial inlet 12 and lies axially interposed between the front wall 7 of the casing 6 and the support disc 23. The annular member 26 has a radially inner surface 27 thereof which delimits a radially inner passage 28 and which diverges in the advancement direction of the flow, i.e. it opens radially towards the support disc 23. Such diverging surface 27 comprises a substantially cylindrical radially inner surface 29, a circular surface that is substantially perpendicular to the rotation axis X-X and defining a front surface 30 of the annular member 26 and a convex connector surface 31 between said radially inner surface 29 and said front surface 30. The front surface 30 bears a sealing gasket 32. The radially inner substantially cylindrical surface 29 has a diameter substantially equal to that of the axial inlet 12.

[0057] The diverging surface 27 of the annular member 26 delimits, together with a surface 33 of the support disc 23 directed towards the axial inlet 12, an annular duct 34 converging towards the ring of stator blades 13 of the first stage 3, 13. The passage section of such convergent annular duct 34 progressively decreases in moving from the axial inlet 12 towards the ring of stator blades 13 of the first stage 3, 13.

[0058] Between the front surface 30 of the annular member 26 and an abutment surface 35 belonging to the support disc 23 and placed in front of said front surface 30, a radial annular passage 15 is delimited, adjacent to the stator blades 13 of the first radial stage 3, 13, which defines the abovementioned radially inner annular inlet opening 15.

[0059] An inlet tube/duct 36 is mounted on the casing 6 at the axial inlet 12. Such inlet duct 36 comprises a first portion 37 directly connected to the axial inlet 12 and coaxial with the rotation axis X-X and a second portion 38 connected to the first portion 37 and placed crosswise with respect to the rotation axis X-X. The illustrated first and second portion 37, 38 are placed at 90 with respect to each other.

[0060] The annular member 26 is borne by a transmission shaft 39 which exits outward from the axial inlet 12 and is coaxial with the rotation axis X-X. The transmission shaft 39 is extended inside the inlet duct 36. In particular, the transmission shaft 39 has a distal end 40 close to the annular member 26 and a proximal end 41, opposite the distal end 40, which exits outward from the inlet duct 36.

[0061] In the illustrated embodiment, the transmission shaft 39 is housed, in a manner such that it can axially slide and rotate, in a sleeve 42 connected and integral with the inlet duct 35 and with the casing 6. The sleeve 42 is joined to the casing 6 by means of struts 43 which are radially extended between the sleeve itself 42 and a radially inner wall of the axial inlet 12. The transmission shaft 39 crosses through the inlet duct 35 at a rear wall 44 of said inlet duct 36. Also the rear wall 44 supports the transmission shaft 39, in a manner such that said shaft 40 can axially slide and rotate.

[0062] The distal end 40 of the transmission shaft 39 exits outward from the sleeve 42 and bears a plurality of radial elements 45 connected to the annular member 26. The annular member 26 is borne by the transmission shaft 39 by means of said radial elements 45. Such radial elements 45 preferably have an aerodynamic profile.

[0063] The proximal end 41 of the transmission shaft 39 exits outward from the rear wall 44 of the inlet duct 36 and is operatively connected to an actuator 46, schematically illustrated, which, when suitably controlled, allows axially moving the transmission shaft 39 in the sleeve 42 and in the rear wall 44 and making it rotate, within the sleeve 42 and the rear wall 44, around a main axis thereof coinciding with the rotation axis X-X of the turbine 1. The actuator 46 is also mounted on the rear wall 44.

[0064] Elastic means 47 are operatively active at the proximal end 41 of the transmission shaft 39 and are configured to push the annular member 26 towards the abutment surface 35. The actuator 46 is single-acting and allows axially moving the annular member 26 away from the abutment surface 35, opposing the elastic means 47, and making it rotate according to a predefined angle around the rotation axis X-X. In the embodiment schematically illustrated in FIG. 1, the elastic means 47 comprise a preloaded mechanical spring integrated in the actuator 46.

[0065] A transmission ring 48 is arranged in the casing 6 around the annular member 26. The transmission ring 48 is axially fixed with respect to the casing 6 but can rotate with respect to said casing 6 around the rotation axis X-X. In addition, the transmission ring 48 is constrained to the annular member 26, for example by means of one or more keys 49, such that it can rotate together with said annular member 26. The key or keys 49 allow the free axial translation of the annular member 26 with respect to the transmission ring 48 and constrain said two elements in the rotation around the rotation axis X-X. The key or keys 49 are, for example, integrally mounted on the transmission ring 48 and inserted such that they can axially slide in slots 50 made in the annular member 26.

[0066] The stator blades 13 of the first radial stage 3, 13, that closer to the axial inlet 12, are mounted on the casing 6 and on the support disc 23 by means of small shafts that allow the orientation thereof around respective adjustment axes Y-Y parallel to the rotation axis X-X (FIGS. 1 and 1A). All the blades 13 of the first radial stage 3, 13 are also connected, by means of pins 51 spaced from the respective adjustment axes Y-Y and parallel to the rotation axis X-X, to the transmission ring 47.

[0067] A control unit, not illustrated, is operatively connected and controls the actuator 46. The control unit allows axially moving the annular member 26 by adjusting the axial size of the radial annular passage 15 (FIG. 1) and also simultaneously orienting all the blades 13 of the first radial stage 3, 13 around the adjustment axes Y-Y so as to vary passage sections 52 delimited between said stator blades 13 (FIG. 1A). In the case of failure of the actuator 46 or of another drawback, the actuator 46 is deactivated and the elastic means 47 quickly push (in a few hundredths of a second, e.g. in about 0.05 s) the annular member 26 and the sealing gasket 32 against the abutment surface 35 of the support disc 23, blocking the flow through the turbine 1.

[0068] In a second exemplifying embodiment of the turbine 1 according to the invention, illustrated in FIG. 2, the structure of the turbine 1 is substantially the same as that described above (for the same elements, the same reference numbers have been used) except for the following two aspects: [0069] the turbine is only radial, i.e. it does not have the auxiliary axial stage of FIG. 1, so that the annular opening of radially outer outlet 16 opens into the diffuser 22; [0070] the annular member 26 can only rotate around the rotation axis X-X (as described for the first embodiment) but it cannot be axially moved, so that also the actuator 46 is only rotational and the elastic means 47 are not present.

[0071] As is visible in FIG. 2, the adjusting device 25 lacks the transmission ring 48. The annular member 26 is directly connected to the stator blades 13 of the first stage 3, 13 by means of the pins 51 and can only rotate a predefined angle with respect to the casing 6 in which it is housed. The control unit allows simultaneously orienting all the blades 13 of the first radial stage 3, 13 around the adjustment axes Y-Y so as to vary the passage sections 52 delimited between said stator blades 13 (as in FIG. 1A).

[0072] In a third exemplifying embodiment of the turbine 1 according to the invention, illustrated in FIG. 3, the turbine 1 is only radial, like that of the second embodiment. In addition, the annular member 26 can only be axially moved along the rotation axis X-X (as described for the first embodiment) but cannot rotate around said rotation axis X-X. The actuator 46 is only axial and the elastic means 47 are present. The blades 13 of the first radial stage 3, 13 are mounted fixed on the casing 6, i.e. they cannot be oriented by rotating them. The annular member 26 has a radial edge 53 in which the same number of through slits 54 are made as are on said blades 13 of the first radial stage 3, 13. Each slit 54 has a shape with the form of the profile of the respective blade 13. Each blade 13 lies slidably inserted in the respective slit 54 and the radial edge 53 is free to translate around the blades 13 while the annular member 26 is moved along the rotation axis X-X. The control unit allows axially moving the annular member 26 by adjusting a height H of the blades 13 and the axial size of the radial annular passage 15. In the case of failure of the actuator 46 or of another drawback, the actuator 46 is deactivated and the elastic means 47 quickly push (in a few hundredths of a second, e.g. in about 0.05 s) the annular member 26 and the sealing gasket 32 against the abutment surface 35 of the support disc 23, blocking the flow through the turbine 1.

[0073] In a fourth exemplifying embodiment of the turbine 1 according to the invention, illustrated in FIG. 4, the turbine 1 is identical to that of the third embodiment but lacks the radial edge 53 and the slits 54.

[0074] In the first, third and fourth embodiments, the annular member 26 is axially mobile between a configuration of complete opening of the radial annular passage 15 (area of the annular passage equal to 100%), in which the gasket 32 of the annular member 26 lies at a maximum distance from the abutment surface 35 of the casing 6, and the abovementioned closed configuration (area of the annular passage 15 equal to 0%).

[0075] In the first embodiment, the annular member 26 can only be stopped in the configuration of complete opening (turbine in operation) or in that of complete closure (turbine blocked) while the adjustment of the mass flow rate is only carried out by means of the orientation of the blades 13 of the first stage 3, 13. In other words, the axial movement of the annular member 26 is only exploited in order to place the turbine 1 in safety conditions in case of emergency.

[0076] In the third and fourth embodiment, the annular member 26 can be stopped in any intermediate position between the two (complete opening and closure) described above, in order to carry out the throttling. In this case, the area of the radial annular passage is a function of the axial position of the annular member (area of the annular passage comprised between 0% and 100%). The axial movement of the annular member 26 (only movement) is exploited both to place the turbine 1 in safety conditions in case of emergency and to adjust the mass flow rate.

[0077] In the above-illustrated first, third and fourth embodiments, the adjusting device 25 can comprise a guide element 55 integral with the casing 6, coaxial with the rotation axis X-X and slidably engaged with the transmission shaft 39. As is visible in FIG. 1B, the guide element 55 is fixed to the support disc 23 and has a guide hole 56 housing the distal end 40 of the transmission shaft 39. The guide hole 56 and the distal end 40 of the shaft 39 delimit a small chamber 57 with variable volume in fluid communication with the convergent annular duct 34 by means of vent channels 58 made in the shaft 39.

[0078] In other embodiments, not illustrated, the turbomachine 1 is a working machine (compressor).

[0079] The present invention also relates to a plant which comprises the turbomachine 1 according to the invention. By way of example, the plant is of ORC (Organic Rankine Cycle) type for the generation of electrical energy and exploits, as source, the energy of geothermal resources. The plant includes a turbine 1 according to the invention. The turbine 1 allows improving the efficiency of the cycle (with respect to the known turbines with fixed geometry) in input conditions different from the nominal conditions as shown in the following examples.

EXAMPLES

[0080] The plant is designed to produce a certain quantity of electrical power P (kW) with a consumption of source fluid m (kg/s) represented by water at 150 C. (temperature of the source) that can be cooled to not less than 80 C. (re-injection temperature).

Example 1

[0081] Following the development of the geothermal field, a condition is encountered of a resource at lower temperature: 135 C. (instead of 150). The objective is to maintain the produced power P substantially constant.

[0082] If the temperature of the source is lowered with respect to the nominal temperature, it is necessary to decrease the evaporation temperature in order to maintain constant the pinch point (minimum temperature difference in the evaporator between the evaporation curve of the organic fluid and the cooling curve of the resource).

[0083] In a known turbine with fixed geometry, the volumetric flow rate is constant and hence, by decreasing the evaporation pressure, the mass flow rate decreases and also the produced power decreases therewith. In order to overcome this drawback with a known turbine with fixed geometry, it is sufficient to increase the flow rate by increasing the re-injection temperature in order to maintain the pinch point constant. In order to increase the flow rate it is therefore necessary to make multiple geothermal wells with respect to those provided (increase of initial investment).

[0084] With the turbine according to the invention, the pinch point is maintained by lowering the pressure at the turbine inlet and by increasing the flow rate (by varying the geometry at the inlet). As is visible in the following table, the increase of mass flow rate (139%) is in any case less than that required (156%) with a known turbine with fixed geometry with consequent lower resource consumption.

TABLE-US-00001 VARIABLE FIXED GEOMETRY GEOMETRY Produced power 100% 100% Mass flow rate of source fluid 156% 139% Volumetric flow rate at the turbine 100% 134% inlet Turbine inlet pressure 100% 84% Thermal power input 100% 109% Source exhaust temperature 90 80

Example 2

[0085] Following the development of the geothermal field, a condition of the resource is encountered at higher temperature: 170 C. (instead of 150). It is desired to maintain constant the mass flow rate of source fluid (number of geothermal wells). In this condition, in case of variable geometry one can proceed with an optimization of the thermodynamic cycle which allows more greatly exploiting the advantages of the higher temperature of the resource in terms of cycle efficiency. In case of variable geometry, the turbine inlet pressure is greater, with higher power P production, as is summarized in the table below.

TABLE-US-00002 FIXED VARIABLE GEOMETRY GEOMETRY Produced power 141% 144% Mass flow rate of source fluid 100% 100% Volumetric flow rate at the turbine 100% 93% inlet Turbine inlet pressure 124% 131% Thermal power input 129% 129% Source exhaust temperature 80 80