Integrated turbine and pump assembly

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

[0001] The present invention relates to high-speed turbopump assemblies and more particularly, to an integrated turbine and pump design whereby the conventional design having a pump or compressor section, a turbine section, and associated bearing and seal components are eliminated in favor of a unitary turbopump assembly.

2. Description of Related Art

[0002] Prior art turbomachinery provides inducer, axial flow, and centrifugal type pumps or compressors which are coupled to an axial or radial flow turbine as a source of power. The pumps can be single stage or multistage depending on the discharge pressure or head required and the density of the fluid being pumped. The turbines can be single stage or multistage and can be of an impulse or reaction type depending on the energy level available in the working fluid. The pump and turbine can be separate units connected together by a coupling for torque transmission or can be mounted on a common shaft. Typically, the rotor is an assembly of numerous parts consisting of pump inducers and impellers, turbine discs or wheels, bearing journals and dynamic seal mating rings; all of which are assembled together on a common shaft through splines or curvic couplings and preloaded together through the use of retainer nuts and bolts to make up the rotor assembly. The housing consists of numerous parts, including inlets, interstage diffusers, volutes, turbine manifolds, nozzles, bearings, labyrinth seal, and dynamic seal; all bolted together with the appropriate static seals to make up the turbopump housing. The rotor components are assembled for balancing purposes but then must be disassembled to facilitate assembly of the turbopump, resulting in relocation unbalance during reassembly of the rotor.

[0003] A typical state of the art liquid hydrogen turbopump, of the type discussed above, has a housing that penetrates the rotating assembly, to a diameter less than that of either the pump impellers or the turbine rotors, at least four times between the first pump impeller and the last turbine rotor. The reasons for these penetrations are (a) the diffuser type utilized, (b) the pump interstage flow path utilized, and (c) the low speed limitations of conventional bearings and seals. As a result, at least six major rotating assembly parts, and six major housing parts, are required to permit the unit to be assembled and disassembled. In addition, the large depth of the penetrations results in a rotating assembly that is quite flexible and, therefore, is subject to operation in the range of several flexural critical speeds. This large number of parts, combined with the critical speed limitations, results in a unit that is costly to assemble and maintain, and that is difficult to operate over a wide throttling range. In addition, the rotational speed limitations of the conventional bearings and seals results in a unit that is relatively large and heavy.

[0004] For example, U. S. Patent 4,482,303 of November 13, 1984 provides a turbo-compressor apparatus having the turbine section and the compressor section back-to-back. A stationary or non-rotating shaft axially supported in the apparatus supports an anti-friction bearing which, in turn, rotationally supports a rotor assembly which has a turbine wheel disposed within the turbine section and a compressor impeller disposed within the compressor section.

[0005] U. S. Patent 4,260,339 of April 7, 1981 defines a turbo compressor apparatus including housing means, rotor means housed within the housing means, fixed shaft means, anchorage means fixedly anchoring the shaft means to the housing means, and bearing means axially and radially locating the rotor means for rotation with respect to the shaft means.

[0006] US Patent 2,083,167 of Dec. 24, 1935 is a turbopump adapted to deliver two different water-miscible liquids to a common mixing chamber. It utilizes a turbine to propel pumps on the shaft. The device in 2,083,167 has a similar construction to the applicant's design in that it has a central turbine and pumps on either end of a common shaft. However, the applicant's design has only two housing sections and one rotor having at least one pump section and a turbine section. The applicant's design has hydrostatic bearings built into the housing and input and output manifolds defined by internal surfaces of the rotor and the housing. Further the applicant's design has a housing which does not break the plane of the impellers for simplicity of assembly.

OBJECTS OF THE INVENTION

[0007] Accordingly, it is an object of the present invention to provide a simplified turbopump design typically having a single integral rotating element and two major housing elements plus ducting.

[0008] Another object of the present invention is to provide a turbopump design having a very rigid rotating element whereby flexural critical speeds are eliminated from the operating speed range.

SUMMARY OF THE INVENTION

[0009] All of these and other objects are achieved by the present invention which provides a turbopump assembly consisting of a first pump section, a second pump section, and a turbine section. The objectives of a minimum number of parts, and a rotating element that is free of flexural critical speeds, are achieved by designing to minimize the number of penetrations of the rotating element by the stationary housing. This is accomplished by (a) placing the centrifugal pump inlets at the ends of the rotating element, (b) combining the bearing and seal functions into single components that are placed at the same diameter as the centrifugal pump impellers, (c) placing the pump flow diffusers and flow collectors at diameters greater than those of the centrifugal impellers (d) placing the turbine rotor between the pump elements at a diameter that approaches, or even exceeds, that of the centrifugal pump impellers, and (e) integrating the turbine inlet and exit manifolds and the pump inlets and volutes into a two piece housing.

[0010] The foregoing and other objects, features and advantages of the present invention will become more apparent in light of the following detailed description of the embodiments thereof as illustrated in the accompanying drawings.

BRIEF DESCRIPTION OF DRAWINGS

[0011] For the purpose of illustrating the invention, there is shown in the drawings embodiments which are presently preferred, it being understood, however, that the invention is not limited to the precise arrangements shown.

Fig. 1 is a cross-sectional oblique view of a turbopump assembly as is known in the prior art,

Fig. 2 is an end view of a turbopump assembly of the present invention,

Fig. 3 is a side elevational view along line 3-3 of Fig. 2,

Fig. 4 is a cross-sectional view taken along line 4-4 of Fig. 2,

Fig. 5 is a cross-sectional view of one embodiment of the turbopump assembly taken along line 5-5 of Fig. 4,

Fig. 6 is an exploded view of the turbopump assembly of Fig. 4,

Fig. 7 is a cross-sectional view of a turbopump assembly having a single stage centrifugal pump and a radial inflow turbine, utilizing the present invention teachings,

Fig. 8 is an end view along line 8-8 of Fig. 7, and

Fig. 9 is a cross-sectional view of a turbopump assembly having a single stage centrifugal pump and an axial flow turbine utilizing the present invention teachings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0012] Referring now to the drawings, wherein like numerals indicate like elements, there is shown in Fig. 1 a turbopump assembly constructed in accordance with the prior art.

[0013] As depicted in Fig. 1, prior art turbopump assembly 10 is provided with a forward three stage pump section 12 and an aft two stage turbine section 14. Forward pump section 12 includes a fluid inlet 16, inducer 18, and three impeller stages 20. Common shaft 22 is associated with forward pump section 12 and aft turbine section 14 of assembly 10. Aft turbine section 14 is also provided with a turbine fluid inlet 24, turbine fluid outlet 26, turbine blades 28 and turbine disc 30. The method of operation of turbopump assembly 10 is characterized by a functioning of the aft turbine section 14 by the introduction of working fluid via 24 which causes the functioning of turbine blades 28 which in turn rotate shaft 22. Rotating shaft 22 functions impellers 20 located on shaft 22 within the pump section 12 of assembly 10 and induces fluid to flow via fluid inlet 16 into pump section 12. From pump section 12, the fluid is transported out of section 12 as shown by the arrow at high pressure for further utilization.

[0014] With reference to the drawings, Fig. 4 depicts a turbopump assembly constructed in accordance with the present invention and designated generally as 40. Turbopump assembly 40 includes a first pump section housing 42 and a second pump section housing 70, each of which may be made of aluminum, titaniam or high strength steel alloys or a plastic material suitable for the design requirements of assembly 40. In addition to housings 42 and 70, assembly 40 is further provided with rotating shaft 51 as shown in Figs. 4 and 6 having a largely cylindrical constant diameter external surface.

[0015] Rotatable shaft 51 is positioned within housings 42 and 70 and in cooperation with said housings defines a first pump 43 within first pump section housing 42 and a second pump 71 within second pump section housing 70 and a center turbine 50 with manifolds 94 and 86. In other words, if the shaft and housings of Fig. 6 were joined, then as shown in Fig. 4, the composite structure would provide a first or forward pump 43 and an aft pump 71 having first pump section fluid inlet 44 and second pump section inlet 72, respectively and a center turbine 50 with an inlet manifold 86 and an exit manifold 94.

[0016] Referring again to Fig. 4, the first or forward pump generally designated 43 includes an inlet 44, an inducer 46, an impeller 48, a diffuser 54, and a volute 56. Internal manifolds 94 defined by an internal surface 64 (see Fig. 6) of the first pump section housing 42 and an external surface 66 of shaft 51 embody the turbine exhaust manifolds. In similar fashion, second pump generally designated 71 includes inlet 72, impeller 76, diffuser 78, and volute 80. Internal manifolds 86 defined by an internal surface 98 of the second pump housing 70 and external surface 100 of shaft 51 embody the turbine inlet manifold 86.

[0017] By this configuration, first or forward pump 43, second or aft pump 71, and center turbine 50 form an integrated turbine and dual pump turbopump configuration.

[0018] In order for working fluid to be processed by turbopump assembly 40, the first pump section housing 42 includes fluid inlet 44 which directs fluid past inducer 46 associated with forward impeller hub 52 of rotating shaft 51. The forward impeller hub 52 also includes pump impeller 48 attached thereto. Located within first pump section housing 42 is diffuser 54. Diffuser 54 communicates with volute collector 56 which in turn is associated with fluid passage 58 which supplies lubricating fluid to adjacent hydrostatic bearing/seal surfaces 59.

[0019] A forward volute discharge 60 is formed proximate volute collector 56 and via interpump crossover 62 allows for fluid communication between first pump 43 and second pump 71 defined by housing 42, housing 70 and rotating shaft 51.

[0020] Second pump inlet 72 in the aft end of second pump section housing 70 as shown in Fig. 4 includes impeller hub 74 of shaft 51, second pump impeller 76, second pump diffuser 78 and second pump volute collector 80. Fluid from volute discharge 60 flows through interpump crossover 62, into inlet 72 and second pump 71.

[0021] As will be explained in greater detail hereinbelow, volute collector 80 communicates with second pump volute discharge 82 (see Figs. 2 and 3). The turbine inlet 84 communicates with inlet manifold 86 and stationary inlet nozzle vanes 88 attached to second pump section housing 70 to supply the working fluid to the turbine rotor blades 92. A chamber 90 is defined by second pump section housing 70 and rotating shaft 51. Within chamber 90 as seen in Fig. 4, nozzle vanes 88 are positioned approximate to shaft rotor blades 92 which are attached to rotating shaft 51. Chamber 90 also forms a conduit between inlet manifold 86 and the turbine exit manifold 94 of the forward pump housing 92. Exit manifold 94 then communicates with manifold outlet 96 (see Fig. 3) which directs the turbine working fluid out of turbopump assembly 40 to an end user such as a rocket engine thrust chamber.

[0022] In operation a fluid such as liquid hydrogen is supplied from a fuel system holding tank (not shown) to the first pump inlet 44 and gaseous high energy fluid is supplied to the turbine inlet 84.

[0023] The pump fluid enters the first pump section 43 through inlet duct 44, and passes into inducer 46, which enables the pump to operate at low inlet pressure. Then, the majority of the first pump section energy input occurs in impeller 48. The excess kinetic energy in the flow leaving the impeller is converted to static pressure in diffuser 54. The flow is then collected in volute collector 56, and directed into discharge ducts 60, which lead to pump section flow crossover ducts 62. The crossover ducts then merge and direct the flow into inlet 72. All of the second pump section energy input occurs in impeller 76. From there, the flow situation is analogous to that at the exit to the first pump section impeller, i.e., the flow is diffused in diffuser 78, collected in volute collector 80, and directed into discharge ducts 82 (which are shown in Figures 2 and 3). From there, the fluid is directed to a user system such as a rocket propulsion system.

[0024] A portion, or all of that pump flow is returned, after being heated by combustion and/or heat transfer, to drive the turbine. It enters the turbine as a moderately high temperature gas through turbine inlet ducts 84 (see Figure 4), and passes into the turbine inlet manifold 86. Turbine nozzle blades 88 align that flow for efficient passage through the turbine rotor blades 92, which convert the kinetic energy in the nozzle exit flow to a torque that drives the two pump sections. After leaving the rotor blades, the flow is collected in turbine exit manifold 94, and delivered to turbine discharge ducts 96 (see Figs. 2 and 3). From there, the flow is delivered, depending on the engine cycle, either to the main combustion chamber, or to a turbine exhaust thruster.

[0025] The rotating element is supported, in the radial direction, by combined hydrostatic bearings/seals that are located on both sides of both impeller exits.

[0026] In conventional turbopumps, the rotor center of rotation is established by radial bearings and the concentricity of the impeller shroud and interstage seals must be maintained with respect to the bearings. By combining the function of the bearings and seals into the hydrostatic bearings located on both sides of the impeller discharge, concentricity control between bearings and seals is eliminated and normal differential pressure leakage is utilized to provide the hydrostatic bearing stiffness and damping.

[0027] For the first pump section 43, the first of these combined bearings is located in the radial concentric space between the inducer/impeller shroud 49 and housing 42, and the second of these combined bearings is located on the other side of impeller 48, and is fed by flow that passes from volute collector 56 to secondary bearing supply 58. Similar combined bearings support the radial loads in the second pump section 71. The axial thrust loads are pressure balanced by the balance piston flow that is delivered to the radial face outside of inducer 46 through the balance piston flow duct 47 that passes from second pump section volute 80 to the aforementioned radial face.

[0028] With this arrangement of turbopump components, it is apparent that the housing consists of only three parts; first pump section housing 42, second pump section housing 70, and pump section crossover duct 62. The lack of housing penetration into rotating element 51, to diameters less than those at the tips of impellers 48 and 76, permits this great simplification. It also permits the rotating assembly to consist of only one part. Finally, it maximizes the diameter of that rotating assembly, thereby eliminating flexural critical speeds from the turbopump operating range.

[0029] Alternate turbopump configurations to which this principle is applied are illustrated in Figs. 7, 8, and 9. These configurations differ from that of Fig. 4 in that they only have one pump section (or stage) and, therefore, have their turbines on the other end of the shaft rather than in the middle. The configuration illustrated in Figs. 7 and 8 has a radial inflow turbine, and that of Fig. 9 has an axial flow turbine. However, both configurations utilize the combined hydrostatic bearings and seals, and the principle of no housing penetration to a diameter of less than that of the pump impeller, to obtain the same high degree of simplicity, and the same resistance to critical speeds, as were obtained with the configuration in Fig. 4.

[0030] Similarly, as in the turbopump assembly depicted in Fig. 4, the turbopump assemblies shown in Figs. 7-9 provide an inside diameter of the respective diffuser, collector and nozzle equal to or greater than the turbopump impeller tip. In addition the assemblies of Figs. 7-9, as with the embodiment of Fig. 4, provide a minimum diameter, for each assembly diffuser, collector and turbine stators, equal to or greater than the impeller tip terminus.

[0031] In this manner the turbopump assemblies (Figs. 1-9) exhibit a housing configuration that seletively precludes penetration by the aforementioned components into the assembly shaft of the turbopump assemblies.

[0032] Referring to Figs. 7 and 8, fluid flow of the type discussed above, enters the pump through inlet 100 and passes through inducer 102, which enables the pump to operate at low inlet pressure. Then, the bulk of the pump energy input to the flow occurs in impeller 104. Next, the flow passes into radial diffuser 106, where the excess kinetic energy is converted to static pressure. From there, the flow passes into volute collector 108, which directs it into the pump exit ducts 110.

[0033] To drive this pump, turbine drive gas enters the turbine through turbine inlet ducts 112, and passes into the turbine inlet manifold 114. It is directed at radial inflow turbine rotor 118, at the appropriate angle, by inlet nozzles 116 (see Fig. 8). As the flow passes radially inward, rotor 118 converts the kinetic energy in the drive gases into mechanical energy to drive the pump on the other end of shaft 122. The spent drive gases then exit the turbine axially through duct 120.

[0034] Shaft 122, which has the pump impeller on one end and the turbine rotor on its other end, is supported by combines hydrostatic bearings and seals 128, 130, and 132, that are located at the same diameter as that of the pump impeller tip and the turbine rotor tip. Through this arrangement, the configuration in Figures 7 and 8 requires only three parts, the shaft/rotor/impeller 122, and housing parts 124 and 126. It thereby achieves the same simplicity and ruggedness that was exhibited by the configuration shown in Fig. 4.

[0035] Also shown in Fig. 7 is an annular gap 125 which thermally isolates the higher temperature turbine from the lower temperature pump during operation.

[0036] In the configuration shown in Fig. 9, the pump function is identical to that just discussed. The flow enters the pump through inlet 200 and passes through inducer 202, which enables the pump to operate at low inlet pressure. Then, the bulk of the energy input to the flow occurs in impeller 204. Next, the flow passes into radial diffuser 206, where the excess kinetic energy is converted to static pressure. From there, the flow passes into volute collector 208, which directs it into a pump exit duct (not illustrated).

[0037] To drive this pump, the turbine drive gas enters the turbine through a turbine inlet duct (not shown) and passes into turbine inlet manifold 210, which aligns it and directs it into axial turbine rotor blades 212. These turbine rotor blades expand and convert the gas energy into mechanical energy to drive the pump through shaft 218. Upon leaving the rotor blades, the gases are diffused and turned axially by stationary stator vanes 214. The spent gases then leave the turbine through exit duct 216.

[0038] Shaft 218, which has the pump impeller on one end and the turbine rotor on its other end, is supported by combined hydrostatic bearings and seals 224, 226, and 228, that are located at the same diameter as that of the pump impeller tip. Through this arrangemwent, the configuration of Fig. 9 consists of three parts, the shaft/rotor/impeller 218, and housing sections 220 and 222.

[0039] By combining the bearing and seal functions into a single unit and placing them at the same diameter as that of the pump impeller tip(s), by placing the pump inlet(s) at the end of the shaft, and by making the diameters of the pump diffuser/collector and the turbine manifold nozzle equal to or greater than that of the pump impeller tip(s), the following features result:

(a) The housing that contains the diffusers, collectors, manifolds, and nozzles can be made of only two parts that, when unbolted, can be slipped off the two ends of the rotating assembly.

(b) The rotating assembly that contains the shaft, the pump impeller(s), and the turbine rotor can be made of only one part.

(c) The above features translate into an overall turbopump assembly that consists of only four parts if there are two pump sections (as in Figure 4), and only three parts if there is one pump section (as in Figures 7 and 9).

(d) The minimum diameters of the rotating assembly are maximized, thereby minimizing the possibility of operating at flexural critical speeds which, in turn, greatly enhances operational stability, range, and reliability.

Claims

1. A turbopump assembly comprising:

a housing having a first portion (42) and a second portion (70) with a parting plane therebetween to facilitate ease of assembly of the housing,

a one piece rotor (51) having at least one pump section (43, 71) having impellers (48, 76), and a turbine section (50) having turbine blades (92),

the housing portions (42, 70) having a larger diameter than the impellers (48, 76) on the pump section (64, 96) of the rotor (51), and the housing portions (42, 70) having a larger diameter than the turbine sections, for ease of inserting the rotor (51) in the housing (40, 72),

the pump section (43, 71) includes an internal manifold (94, 86) defined by an internal surface of the pump section (64, 96) and an external surface of the rotor (66, 100), the housing (40, 72) having a hydrostatic bearing and seal portion (59), the hydrostatic bearing portion being proximate the rotor (51) to radially support the rotor (51) and prevent contact between the rotor and the housing (42, 70) while the rotor (51) is rotating and the seal portion (59) proximate the rotor (51) limiting loss of a hydrostatic fluid.

2. A turbopump assembly as in claim 1 wherein,
   the one piece rotor (51) has two pump sections (43,71) with the turbine section (50) therebetween.

3. A turbopump assembly as in claim 1 wherein,
   there is an inducer (46) on the rotor (51) for a first fluid pumping step before the fluid is engaged by the impeller (48).

4. A turbopump assembly as in claim 1 wherein,
   a volute collector (56,80) is located in the housing (42,70) for collecting the fluid for discharge.

5. A turbopump assembly as in claim 1 wherein,
   a diffuser (54,78) is located in the housing (42,70) for converting fluid velocity to static pressure.

6. A turbopump assembly as in claim 1 wherein,
   a thermal insulation gap (125) is placed in the housing near the turbine section (118) to thermally insulate the pump section (124) from the turbine section (126).

7. A turbopump assembly as in claim 2 wherein,
   the housing has a front end and a back end and the pump inlets (44,72) are at the ends of the housing (42,70).

8. A turbopump assembly as in claim 2 wherein,
   a balance piston flow duct (47) in the housing provides (42,70) axial stability for the rotor (51).

9. A turbopump assembly as in claim 1 wherein,
   the turbine section (50) of the rotor (51) has a different diameter than at least one pump section (43,71) and the inside diameter of the housing portions (42,70) correspond to the diameter of the rotor (51) so that the rotor (51) slides into the first portion (42) and the second portion (70) of the housing unobstructed before the housing portions are attached.

10. A turbopump assembly as in claim 1, wherein the hydrostatic bearing and seal portion (59) acts as the dynamic seal to control the leakage rate between the pump section (43,71) and the turbine section (50).

11. A turbopump assembly as in claim 1, wherein the pump section (43,71), and the turbine section (50) are contained in the housing with only internal leakage between the pump section (43,71) and the turbine section (50), whereby there is no external leakage of pumped fluids.

12. A turbopump assembly as in claim 2, wherein housing (42, 70) and impellers (48, 76) have a uniform diameter in the pump sections (43, 17) of the rotor (51).

Ansprüche

1. Turbopumpenanordnung mit:

einem Gehäuse, das einen ersten Abschnitt (42) und einen zweiten Abschnitt (70) mit einer Trennfläche dazwischen aufweist, um einen einfachen Zusammenbau des Gehäuses zu erleichtern,

einem einstückigen Rotor (51), der zumindest einen Pumpenabschnitt (43, 71) mit Laufrädern (48, 76) und einen Turbinenabschnitt (50) mit Turbinenschaufeln (92) aufweist,

welche Gehäuseabschnitte (42, 70) für ein einfaches Einsetzen des Rotors (51) in das Gehäuse (40, 72) einen größeren Durchmesser als die Laufräder (48, 76) an dem Pumpenabschnitt (64, 96) des Rotors (51) und einen größeren Durchmesser als die Turbinenabschnitte haben,

welcher Pumpenabschnitt (43, 71) eine durch eine Innenfläche des Pumpenabschnitts (64, 96) und eine Außenfläche des Rotors (66, 100) definierte interne Leitung (94, 86) enthält, welches Gehäuse (40, 72) einen hydrostatischen Lager- und Dichtungsabschnitt (59) aufweist, wobei der hydrostatische Lagerabschnitt nahe dem Rotor (51) liegt, um den Rotor (51) radial zu tragen und einen Kontakt zwischen dem Rotor und dem Gehäuse (42, 70) zu verhindern, während sich der Rotor (51) dreht, und der Dichtungsabschnitt (59) nahe dem Rotor (51) einen Verlust an hydrostatischem Fluid begrenzt.

2. Turbopumpenanordnung nach Anspruch 1, bei der
   der einstückige Rotor (51) zwei Pumpenabschnitte (43, 71) mit dem Turbinenabschnitt (50) dazwischen aufweist.

3. Turbopumpenanordnung nach Anspruch 1, bei der
   ein Vorlaufrad (46) auf dem Rotor (51) für einen ersten Fluidpumpschritt vorhanden ist, bevor das Laufrad (48) mit dem Fluid beaufschlagt wird.

4. Turbopumpenanordnung nach Anspruch 1, bei der
   sich ein Ausströmraumkollektor (56, 80) in dem Gehäuse (42, 70) zum Sammeln des Fluids zum Ausströmen befindet.

5. Turbopumpenanordnung nach Anspruch 1, bei der
   sich ein Diffusor (54, 78) in dem Gehäuse (42, 70) zum Umwandeln von Fluidgeschwindigkeit in statischen Druck befindet.

6. Turbopumpenanordnung nach Anspruch 1, bei der
   eine Lücke (125) zur thermischen Isolierung in dem Gehäuse nahe dem Turbinenabschnitt (118) angeordnet ist, um den Pumpenabschnitt (124) von dem Turbinenabschnitt (126) thermisch zu isolieren.

7. Turbopumpenanordnung nach Anspruch 2, bei der
   das Gehäuse ein vorderes Ende und ein hinteres Ende aufweist und die Pumpeneinlässe (44, 72) an den Enden des Gehäuses (42, 70) liegen.

8. Turbopumpenanordnung nach Anspruch 2, bei der
   eine Ausgleichskolben-Stromleitung (47) in dem Gehäuse (42, 70) für eine axiale Stabilität des Rotors (51) sorgt.

9. Turbopumpenanordnung nach Anspruch 1, bei der
   der Turbinenabschnitt (50) des Rotors (51) einen verschiedenen Durchmesser als zumindest ein Pumpenabschnitt (43, 71) hat und die Innendurchmesser der Gehäuseabschnitte (42, 70) dem Durchmesser des Rotors (51) so entsprechen, daß der Rotor (51) ungehindert in den ersten Abschnitt (42) und den zweiten Abschnitt (70) des Gehäuses gleitet, bevor die Gehäuseabschnitte angebracht werden.

10. Turbopumpenanordnung nach Anspruch 1, bei der
   der hydrostatische Lager- und Dichtungsabschnitt (59) als die dynamische Dichtung wirkt, um die Leckrate zwischen dem Pumpenabschnitt (43, 71) und dem Turbinenabschnitt (50) zu steuern.

11. Turbopumpenanordnung nach Anspruch 1, bei der
   der Pumpenabschnitt (43, 71) und der Turbinenabschnitt (50) in dem Gehäuse mit allein einem internen Leckverlust zwischen dem Pumpenabschnitt (43, 71) und dem Turbinenabschnitt (50) enthalten sind, wodurch es keinen externen Leckverlust gepumpter Fluide gibt.

12. Turbopumpenanordnung nach Anspruch 2, bei der
   das Gehäuse (42, 70) und die Laufräder (48, 76) einen gleichmäßigen Durchmesser in den Pumpenabschnitten (43, 71) des Rotors (51) haben.

Revendications

1. Ensemble turbopompe comprenant :

un carter comportant une première partie (42) et une seconde partie (70), un plan de séparation étant prévu entre celles-ci pour faciliter l'assemblage du carter,

un rotor monobloc (51) ayant au moins une partie pompe (43, 71) comportant des roues mobiles (48, 76), et une partie turbine (50) comportant des aubes de turbine (92),

les parties (42, 70) du carter ayant un plus grand diamètre que les roues mobiles (48, 76) de la partie pompe (64, 96) du rotor (51), et un plus grand diamètre que les parties turbine, pour faciliter l'insertion du rotor (51) dans le carter (40, 72),

la partie pompe (43, 71) comprenant un collecteur interne (94, 86) défini par une face interne de la partie pompe (64, 96) et par une face externe du rotor (66, 100), le carter (40, 72) ayant une partie palier hydrostatique et joint d'étanchéité (59), la partie palier hydrostatique étant à proximité du rotor (51) afin de supporter radialement le rotor (51) et d'empêcher un contact entre le rotor et le carter (42, 70) lorsque le rotor (51) est en rotation, et la partie joint d'étanchéité (59) située à proximité du rotor (51) limitant les pertes d'un fluide hydrostatique.

2. Ensemble turbopompe selon la revendication 1, dans lequel le rotor monobloc (51) comporte deux parties pompes (43, 71) entre lesquelles la partie turbine (50) est interposée.

3. Ensemble turbopompe selon la revendication 1, dans lequel il est prévu un aubage d'entrée (46) sur le rotor (51) pour permettre une première phase de pompage de fluide avant que le fluide ne vienne en contact avec la roue mobile (48).

4. Ensemble turbopompe selon la revendication 1, dans lequel un collecteur en volute (56, 80) est situé dans le carter (42, 70) pour collecter le fluide à refouler.

5. Ensemble turbopompe selon la revendication 1, dans lequel un diffuseur (54, 78) est situé dans le carter (42, 70) pour convertir la vitesse du fluide en pression statique.

6. Ensemble turbopompe selon la revendication 1, dans lequel un espace d'isolation thermique (125) est prévu dans le carter, à proximité de la partie turbine (118), pour isoler thermiquement la partie pompe (124) de la partie turbine (126).

7. Ensemble turbopompe selon la revendication 2, dans lequel le carter a une extrémité avant et une extrémité arrière, les admissions (44, 72) des pompes étant situées au niveau des extrémités du carter (42, 70).

8. Ensemble turbopompe selon la revendication 2, dans lequel un conduit d'écoulement formant piston d'équilibrage (47) prévu dans le carter (42,70) assure une stabilité axiale au rotor (51).

9. Ensemble turbopompe selon la revendication 1, dans lequel la partie turbine (50) du rotor (51) a un diamètre différent de celui d'au moins une partie pompe (43, 71), le diamètre intérieur des parties (42, 70) du carter correspondant au diamètre du rotor (51) afin que le rotor (51) s'insère librement dans la première partie (42) et dans la seconde partie (70) du carter avant qu'elles ne soient fixées.

10. Ensemble turbopompe selon la revendication 1, dans lequel la partie palier hydrostatique et joint d'étanchéité (59) sert de joint d'étanchéité dynamique pour contrôler le débit de fuite entre la partie pompe (43, 71) et la partie turbine (50).

11. Ensemble turbopompe selon la revendication 1, dans lequel la partie pompe (43, 71) et la partie turbine (50) sont logées dans le carter moyennant seulement une fuite interne entre la partie pompe (43, 71) et la partie turbine (50), pour qu'ainsi il n'y ait pas de fuite externe de fluides pompés.

12. Ensemble turbopompe selon la revendication 2, dans lequel le carter (42, 70) et les roues mobiles (48, 76) ont un diamètre uniforme dans les parties pompes (43, 71) du rotor (51).

Drawing