EP1528225A1 - Turbomachine and production method for a stator assembly - Google Patents

Abstract

The turbo machine has a guide vane cascade with a blade support ring (6) with a number of adjustable blades (7) arranged around the turbine rotor (4) and forming an axial boundary of a blade housing (13). A bolt or pin (16) is constructed as a spacer and is fitted by one end between the blade support ring and a component (15,29) provided in the turbine casing (2), and by the other end is fixed for the axial spacing of the blade support ring by means of a connecting material (30) which is applied in a molten state but is then temperature resistant. An independent claim is included for a method for the manufacture of a guide vane cascade for a turbo machine.

Description

Field of the invention:

The invention relates to a turbomachine, such as a turbine, a secondary air pump, but especially on a turbocharger. In particular, it is about a turbomachine with a turbine housing with at least one supply channel for a driving fluid, such as the exhaust gas of an internal combustion engine, in which at least a turbine rotor is rotatably mounted about a rotation axis around which the fluid a grid of variable turbine geometry surrounding the turbine rotor radially on the outside can be fed. The guide grid has a blade bearing ring, on each of an associated axis a plurality of adjustable about their respective axis blades is mounted in an axially limited vane space around the turbine rotor, the Exhaust gas can be supplied via the blades in an adjustable amount, which blade bearing ring which forms an axial boundary of a blade space, and with a spacer device to secure an axial distance for the free mobility of Shovels, which spacer means at least one of the blade bearing ring passing through bolt, pin or the like. having.

Background of the invention

Such a turbocharger and such a blade bearing ring is for example from the EP-A-0 226 444 and US-A-5,146,752, respectively. In this case, the axial dimension of the blade space by means of bolts pushed over distance-retaining Spacers secured, which of course a bolt diameter clearly must have excess outer diameter. The applicant also has in one proposed earlier application, spacers approximately in stud shape integral with a Ring form, these spacers are penetrated in each case by a bolt.

Summary of the invention

The invention proceeds in a first step from the knowledge that the efficiency a turbomachine of course, from a high implementation of the driving in Fluid available energy in revolutions of the turbine wheel depends. each Disturbance or any resistance within the flow path must therefore the efficiency undesirably decrease. Because of this realization was in in a further step, how to improve the flow in such a machine can be. It turned out that the previously connected over the or the Bolt lying spacers or spacer knobs around the turbine rotor and in particular in the connection path between the supply channel and turbine rotor one not cause insignificant vortex formation, which contributes to the reduction of the efficiency.

According to the invention, the problem thus identified is solved by the fact that the respective Bolt, pin or the like. itself is designed as a spacer device by passing between the vane bearing ring and a part provided in the turbine housing at one end used at least at other times with the aid of a molten state, but then temperature-resistant Verbindungsmateriales on the axial Distance of the bucket bearing space is fixed. This is only the diameter of the pin or pin in the path of communication of the fluid to the turbine rotor, i. it results a much lower flow resistance than before. In short, it exists the invention in the use of the bolt or pin itself and without a thickening Sheathing as a spacer. It should be under "temperature resistant" a material be understood, which in the operation of the turbomachine, and in particular turbocharger, temperatures do not have the necessary strength loses.

The coatable in the molten state, but then temperature-resistant bonding material may in principle be a brazing material because there are brazing materials that themselves the temperatures of a turbocharger endure (in other turbomachines with lower operating temperatures, this is no problem anyway). However, it is preferred in general, when the determination of the distance is given by welding.

Although it would be possible to solder the respective bolt at both ends or to weld. However, it is preferred if the bolt, pin or the like. one at a time Has thread for screwing and only at the other end with the help of the connecting material is determined, especially by the one-sided connection on the fusible link material yes, a backup against twisting the respective bolt given is.

In principle, the part provided in the turbine housing may be a wall of the turbine housing be yourself, but it is preferable if he from a the blade bearing ring opposite mounting ring is formed, because in this way a pre-assembly the guide grid can be done outside the turbine housing and preassembled so Leitgitter only needs to be fixed in the turbine housing needs.

In the context of the invention, it is quite possible, the bolt or pin of the Side of the part of the turbine housing, so the housing wall or the mounting ring to insert and about the blade bearing ring with the help of the connecting material (in this case, in general, a brazing material) set. However, it is preferable if the bolt, pin or the like. screwed in the blade bearing ring and on the opposite End with the help of the applied in the molten state, but then temperature-resistant Connecting material is attached.

In order to further reduce the flow resistance, it is within the scope of the invention quite possible that the bolt, pin or the like. at least over the the blade storage room traversing length at least approximately facing the axis of rotation Flow profile, e.g. such as a teardrop-shaped profile similar to one Aircraft or ship hull, owns.

As mentioned, the present invention also relates to a method of manufacturing a guide grid for a turbomachine according to the invention. This method is characterized in that only between the blade bearing ring and the turbine housing (2) provided or to be provided part at least one removable spacer is used according to the desired nominal distance, that the bolt, Pen or the like. only then is fixed on the thus determined distance, whereupon the or the spacers is removed or will be.

Brief description of the drawings

Further details of the invention will become apparent from the following description a schematically illustrated in the drawing, preferred embodiment.

Fig. 1

einen Turbolader in Perspektivansicht, teilweise im Schnitt, an dem die vorliegende Erfindung zur Anwendung kommt; und

Fig. 2

einen vergrößerten Schnitt, welcher die Abstandhalteeinrichtung gemäß der Erfindung veranschaulicht; und

Fig. 3

einen gegenüber Fig. 2 vergrößerten Schnitt durch eine besondere Ausführungsform eines erfindungsgemäßen Abstandhaltebolzens nach der Linie III-III der Fig. 2.

Show it:

Fig. 1

a turbocharger in perspective view, partially in section, to which the present invention is applied; and

Fig. 2

an enlarged section illustrating the spacer device according to the invention; and

Fig. 3

a comparison with FIG. 2 enlarged section through a particular embodiment of a spacer bolt according to the invention along the line III-III of Fig. 2nd

Detailed description of the drawings

1, a turbocharger 1 in a conventional manner a turbine housing part 2 and an associated compressor housing part 3 along an axis of rotation R are arranged. The turbine housing part 2 is partially shown in section, so that a blade bearing ring 6 forming a radially outer guide grid, distributed over the circumference Guide vanes 7 about their the blade bearing ring 6 passing through pivot axes. 8 twisted so that they form nozzle cross sections between each other, depending on the location the guide vanes 7, namely radially (as shown) or more tangentially, larger or are smaller and located in the middle on the axis R turbine rotor 4 more or less with the supplied via a supply channel 9 and a central port 10 supplied exhaust gas of an internal combustion engine to apply over the turbine rotor 4 to drive a seated on the same shaft compressor rotor 21. It understands that in the case of other turbomachines with a variable geometry guide Other fluids can be used.

To control the movement or the position of the guide vanes 7 is an actuating device 11 provided. This can be of any nature in itself, but it is preferable if, in a conventional manner, it has a control housing 12 that controls the movement a ram member 14 attached to it controls its movement in known manner on a behind the blade bearing ring 6 (left behind in Fig. 1) the same adjusting ring 5 implement the same in a slight rotational movement. By This rotational movement are about the shafts 8, the vanes 7 in terms of their Rotary position relative to the turbine rotor 4 adjusted so that they are from an approximately tangential an extreme position in an approximately radially extending other extreme position adjustable are. As a result, the exhaust gas supplied via the supply channel of an internal combustion engine more or less supplied to the turbine rotor 4, before it at the along the axis of rotation R extending axial neck 10 exits again. In place of one Torque transmitting shafts 8 it is also known (US-A-4,300,869), a mere Provide stub axle, and the operation of the blades via slots or grooves make.

Between the blade bearing ring 6 and an annular part 15 of the turbine housing part 2 remains a relatively narrow space 13 around the blades 7 a free mobility to allow. Of course, this blade chamber 13 may not be much larger than that Be the width of the blades 7, because then the exhaust energy would suffer leakage. On the other hand, the vane space 13 may not be too tight, because then the blades 7 could jam. This is especially important because yes especially in the case of a turbocharger 1 by the hot exhaust gases with a certain thermal expansion of the material must be expected.

Therefore, this blade space 13 and the distance of the blade bearing ring 6 from to secure opposite bearing ring 15 of the turbine housing 2, without doing a strong turbulence of the flowing from the supply channel 9 to the turbine rotor 4 exhaust gases To have to accept, according to the invention as a spacer at least one relatively thin fastening bolts 16 used, whose attachment is now on the basis of FIG. 2 should be described.

2, the turbine housing 2 with a flange 17 of a bearing housing connected, from which a cylindrical piece 40 projects into the turbine housing 2 and the shaft 35 of the turbine rotor 4 stores. The turbine housing 2 comprises the already mentioned, the turbine rotor 4 surrounding supply channel 9 for the turbine rotor 4 driving Fluid, a rotor chamber 23 and the axial nozzle 10, through which the fluid or the Exhaust is released again.

In order to supply fluid to the turbine rotor 4 in a regulated or controlled amount, is Output of the supply channel 9 or before the rotor chamber 23 provided a device, the well-known in the art under the name "Leitgitter variable turbine geometry" is. This guide grid essentially has a turbine rotor 4 concentric surrounding wreath of movable, housed in a vane space 13 vanes 7, which at the fixedly connected with them adjusting shafts 8 (Fig. 1) in one the turbine rotor 4 coaxially surrounding blade bearing ring 6 are mounted.

The rotation or adjustment of the adjusting 8 can in a conventional manner be done via the actuator 11 to the control housing 12, the control movement the attached to it, only dash-dotted lines indicated plunger member 14th (Fig. 1), whose movement via an actuating lever 18, one connected thereto Actuating shaft 19 and for example via an opening in a behind the vane ring 6 located adjusting ring 5 engaging eccentric 20 in a slight rotational movement of this ring 5 is implemented around the axis R. Because in the adjusting ring 5 can be in a known manner, the free ends of the levers or heads be mounted, which are fixed to the adjusting shafts 8 (in Fig. 1, left of the shaft 8).

As a result of this rotational movement, the guide vanes 7 are positioned above the shafts 8 their rotational position relative to the turbine rotor 4 adjusted so that it is approximately tangential extending an extreme position in an approximately radially extending other extreme position are adjustable. As a result, the exhaust gas supplied via the supply channel becomes a Internal combustion engine more or less supplied to the turbine rotor 4, before it at which extends along the axis of rotation R extending axial neck 10 again. All these Arrangements are known in principle. In this case, the adjusting ring 5 via rolling elements 22 mounted in a cage ring 23 on a shoulder 32 of the blade bearing ring 6 rolling off be, as it corresponds to an older proposal of the applicant.

In order to secure the axial (with respect to the axis R) dimension of the blade space 13, it is advantageous, instead of limiting it on the one hand by the blade bearing ring 6 and on the other hand by the of an annular wall of the turbine housing. 2 formed bearing ring 15 interpose a mounting ring 29, for example slid on an annular shoulder 24 of the turbine housing or the bearing wall 15 becomes. Because in this way it is possible, the blade bearing ring 6 with the riding on adjusting ring 5 on the one hand, including the blade 7 and the mounting ring 29 pre-assemble on the other side and then (before mounting the bearing housing with the part 40) into the turbine housing 2 or the annular shoulder 24.

In order to secure the necessary axial distance for the blade space 13 z, is in the Pre-assembly a spacer screw 16, suitably from the side of the mounting ring 29 ago to screw into a threaded bore 25 of the blade bearing ring 6. The Screw 16 is preferably a stud, commonly also called worm or Grub screw is known and represents a headless screw. Here is the depth of the Penetration of the screw 16 into the bore 25 is not critical. The stud 16 has prefers a smooth surface following the screw section 26 (ie is in the Vane storage space 13 without thread) to the flow as low as possible resistance oppose. In this case, the cylindrical surface of the stud 16th expedient a maximum roughness number Rz of 25, preferably of a maximum of 16, on.

Subsequently, in the blade storage room 13, a spacer with the desired Dimensions, e.g. a piece of wood of the appropriate thickness or another body, inserted, so that so that the desired width of the blade chamber 13 is determined. Then it will this distance by soldering or (preferably) welding the screw 16 with the help a weld 30 secured, at the same time also a rotation for the screw 16 results and unintentional unscrewing from the threaded hole 25 is effectively avoided as a result of shock or vibration. The out Wood or other material existing spacer can then after pre-assembly the guide grid with the vanes 7 are easily removed. Just when the guide grid is pre-assembled before it pushes it into the turbine housing 2, let easy for the attachment of the softened connection material soldering or Use welding machines, so that the inventive method cost can be carried out.

It is understood that the arrangement could be reversed by the screw 16 screwed into the mounting ring 29 and welded to the blade bearing ring 6, preferably but soldered. It would also be possible to form the bolt 16 without thread and soldered or welded at both ends. It is also understandable that one could also use spacers on the spacer screws 16, but would need These then absorb no axial forces and could therefore be thinner, i. with less Flow resistance as in the prior art, running. In this latter In this case, the spacers would not have to be removed at all. For such The remaining sleeve is then preferably the same as above with respect to the surface the stud and its smoothness was said.

An additional measure to improve the flow conditions of the supply channel 9 to the rotor chamber 23 may be located in that the bolt, pin or the like. At least 16 over the the blade storage room 13 traversing length at least approximately has against the rotation axis R facing flow profile, as on hand Fig. 3 is illustrated. It is then to the circular threaded portion 26 of the screw 16 is provided an approximately drop-shaped flow profile 31, which down (relative to Figs. 2 and 3) in the direction of the axis of rotation R has. This training also facilitates the partial introduction of the weld 30 (Fig. 2) between the end portion of the bolt 16 and the inner surfaces of the receiving it Bore of the mounting ring 29. The flow profile can thereby in each case desired way to be optimized, as it is from shipbuilding or aircraft is known, for example by also the upwardly facing side of the bolt 16 more or less sharpened.

In any case, it can be seen that by using only one bolt (screw, Pin or the like.), Instead of such with a surrounding casing for the Distance assurance, the flow resistance is reduced. In principle, it would evt. suffice to secure only the distance at the junction of the supply channel 9 so, whereas be provided at other locations a conventional distance assurance can, but it is understood that it is preferable if the distance over the whole Scope of the blade bearing ring 6 relative to the mounting ring 29 and the of a Turbine housing wall formed bearing ring 15 (Fig. 1) in the manner according to the invention is secured.

In Fig. 2, a stud 16 has been shown as a spacer pin, wherein the Screw slot 33 at the opposite end of the threaded portion 26 of the Screw 16 is provided. Of course this is not absolutely necessary, rather could the screw slot 33 are also provided at the same end. Instead of one Stud 16 could also be used with a capscrew, but with it the attachment the weld 30 may be more difficult or inefficient.

LIST OF REFERENCE NUMBERS

1 turbocharger 2 turbine housing 3 compressor housing 4 turbine rotor 5 adjusting 6 Nozzle ring 7 shovel 8th Wave v. 7 9 supply channel 10 central spigot 11 actuator 12 control housing 13 blade space 14 plunger member 15 Bearing ring v. Second 16 Spacer bolts 17 flange 18 actuating lever 19 actuating shaft 20 eccentric 21 compressor rotor 22 rolling elements 23 cage ring 24 annular shoulder 25 Threaded hole v. 6 26 Thread section v. 16 29 mounting ring 30 Weld 31 flow profile 32 shoulder 33 screw slot 35 Wave v. 4 40 Cylinder piece of the bearing housing

Claims (10)

Turbomachine comprising: a turbine housing (2) having at least one driving fluid supply passage (9) in which at least one turbine rotor (4) is rotatably mounted about an axis of rotation, and the fluid over a guide vanes of variable turbine geometry surrounding the turbine rotor (4) can be supplied, which guide vanes has a blade bearing ring (6) on each of which an associated axis (8) has a multiplicity of blades (7) which can be adjusted about their respective axis (8) an axially limited vane space (13) is mounted around the turbine rotor (4), the fluid so over the blades (7) can be supplied in an adjustable amount, which vane bearing ring (6) which forms an axial boundary of a vane space (13), and a spacer device for securing an axial distance for the free mobility of the blades (7), which spacer device at least one of the blade bearing ring passing through bolt, pin or the like. (16), characterized in that
the respective bolt, pin or the like. (16) itself as a spacer means is formed by one end between the blade bearing ring (6) and provided in the turbine housing (2) part (15; 29) used and at least at the other with the aid of a coatable in the molten state, but then temperature-resistant bonding material (30 ) is fixed to the axial distance of the blade storage space (13). Turbomachine according to claim 1, characterized in that it is designed as a turbocharger (1) with a on the shaft (35) of the turbine rotor (4) seated compressor rotor (21). Turbomachine according to claim 1 or 2, characterized in that the determination of the distance by welding (30) is given. Turbomachine according to one of the preceding claims, characterized in that the bolt, pin or the like. (16) at one end has a thread (26) for screwing and only at the other end by means of the connecting material (30) is fixed. Turbomachine according to claim 1, characterized in that the bolt, pin or the like. (16) is designed as a stud. Turbomachine according to one of the preceding claims, characterized in that the part provided in the turbine housing (2) is a mounting ring (29) lying opposite the blade bearing ring (6). Turbomachine according to one of the preceding claims, characterized in that the bolt, pin or the like. (16) screwed into the blade bearing ring (6) and fixed at the opposite end by means of the order in the molten state, but then temperature-resistant bonding material (30). Turbomachine according to one of the preceding claims, characterized in that the bolt, pin or the like. (16) at least over the blade bearing space (13) traversing a smooth surface, for example, with a maximum roughness number of 25, in particular of 16, and / or has at least approximately against the axis of rotation (R) pointing flow profile (31). Method for producing a guide grid according to one of the preceding claims, characterized in that at least one removable spacer corresponding to the desired nominal distance is inserted between the blade bearing ring (6) and the part (15; 29) provided or to be provided in the turbine housing (2) in that the bolt, pin or the like. (16) is then set to the so determined distance, after which the or the spacer is optionally removed or will. A method according to claim 9, characterized in that the guide grid is preassembled in compliance with the steps of claim 8 and only thereafter in the turbine housing (2) is used.

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