EP1128023A1 - Turbine rotor blade - Google Patents

Abstract

The invention relates to a moving turbine blade comprising a blade profile (1) with inner cooling which extends out from a blade platform (2) adjoined by a blade foot (4), said blade foot engaging with a turbine disk (3) and having a radial cross-section with an area (5) whose width (6') increases towards the blade platform (2). The aim of the invention is to configure a moving turbine blade of this type in such a way as to enable the moving blade profile to be lengthened. To this end, the blade foot (4) has a hollowed-out section (7) which opens out in the direction facing away from the platform, which comes to a dead end on the platform side and which has a widened cross section in the area (5) of the blade foot (4) whose width (6') increases.

Description

The invention relates to a turbine blade, with a internally uncooled blade profile that extends from a blade platform extends from which extends into a turbine disc engaging blade root adjoins its radial Cross section to the blade platform an area increasing Width.

To increase the efficiency or cross-section of gas turbines are the blade profiles of the turbine blades extended as far as possible to to achieve better utilization of the hot gas flowing past. This extension of the blade profile is however through limited several parameters.

Due to the extended blade profiles and the thereby enlarged moving mass becomes, for example, a hub area the turbine disc due to the attacking centrifugal force charged. This is done by increasing the load-bearing area in the hub area counter by axially extending the disc tries. However, this extension option is limited. With enlarged blade profiles, not only that Hub more stressed, but also the area in which the Turbine blades with their feet in holding recesses in the Outside circumference of the turbine disc are used. An extension the blade profiles could also be radial to the disc hub would take place, but this would make the holding recesses of the outer circumference, their distance would be closer and thus the disc area between them more burdened. However, this burden is only minor Dimensions can be increased without damaging the turbine disk to risk.

The object of the present invention is therefore a turbine blade to create an extension of the blade profiles allows without or with only a minor Increase local loads on the turbine disc or from blade feet.

The object is achieved in that the blade root is a has open cavity facing away from the platform, the platform side ends blindly and in the area of increasing width of the Blade base is widened in cross section.

The blade root is usually used to ensure stability solidly trained and shows compared to the rest Dimensions of the turbine blade have a large cross section on. So its mass is high and it has a large proportion on the one that occurs when the turbine disc rotates Centrifugal load on the turbine disc and the holding devices for the shovel. Due to the hollowing out the mass of the foot and thus the centrifugal force considerably. The special form of the excavation, namely one cross-sectional widening on the longitudinal walls in the area increasing width of the blade root ensures a optimal use of the shape of the blade root in view on a decrease in mass. Because the hollowing out ends blindly on the platform side, are also the stability requirements, which in particular in the area between platform and Blade profile due to diverse strong forces and temperature attack are very high, met. The invention enables thus at the same time to keep the mass of the shovel low and to maintain or even improve their stability. By reducing the weight, the average tension level lowered in the foot area and tension peaks on holding teeth of the foot and the adjacent turbine disc, resulting in an extension of the life of the turbine blade and especially to improve durability of the foot leads. It is therefore without endangering stability the turbine blade and while maintaining the shape of the foot possible to extend the blade profile to the outside and thus increase the efficiency of the turbine.

Good stability of the platform-side blade profile area is given by the fact that the cavity is in a transition area between the blade root and below one Platform top of the platform ends. Above the top of the platform the force on the bucket is special high and the bucket is narrower than in the platform area educated. However, the excavation ends below the The top of the platform is the force applied by the stable Sufficient platform and the adjacent areas intercepted.

To avoid voltage peaks and thus locally excessive high loads it is suggested that the hollowing out of predominantly rounded walls are limited and in arched Form ends below the platform top.

A very large reduction in mass is given by the fact that Longitudinal walls of the cavity over almost the entire length of the Blade root and transverse walls over almost the entire width of the blade root, the walls of the cavity ensure sufficient stability in the event of a centrifugal attack.

For the most part, centrally attacking forces are good at massive areas of the bucket passed without the walls the excavation too much if the excavation in middle area has the greatest height and to the transverse and Longitudinal walls fall off.

If the longitudinal walls of the cavity when approaching the platform-side end while maintaining a minimum wall thickness steadily on the transverse walls of the cavity widen, weight loss is improved and at the same time an abrupt change in curvature leading to local Stress maxima leads, when transitioning to a rounded one End area avoided.

The hot working gases particularly stress that edge area the shovel that is the first to flow directly becomes. The higher strength requirements on the hot gas inflow side is taken into account that the minimum wall thickness near a hot gas inflow side is larger than at the hot gas outflow side.

A material and mass-saving increase in the strength of the Foot is given in that the blade root from between its longitudinal walls trained cross struts is reinforced. The forces acting on one longitudinal wall of the cavity are through the cross struts to the other longitudinal wall of the Excavation and passed through both walls into the turbine disc, without endangering the stability of the excavation. Due to the further reduction in mass also occurs due to the reduced centrifugal load further relief of the foot.

If the cross braces on the platform side of the walls of the cavity and / or from the end of the blade root facing away from the platform Having a distance is an additional weight saving given while maintaining stability.

Optimal transmission of the forces takes place in that Positions and shapes of the cross struts in a line of force are adapted by the attacking on the blade profile Centrifugal forces arise. By an adjusted number and Shape of the cross struts it is therefore possible on the one hand that Reduce mass of the blade root by the walls the hollowing out due to the supporting effect of the cross struts can be made thinner, and at the same time one more homogeneous stress curve along the long sides of the cavity due to the support provided by the cross struts.

The particularly high attacking forces in the middle area are intercepted by the cross struts of the cavity have the greatest height in the middle and to one decrease the height of the sloping course of the excavation.

Fig.1 einen radialen Querschnitt durch einen Fußbereich einer Turbinenschaufel,

Fig.2 einen Längsschnitt durch einen Fußbereich einer Turbinenschaufel nach Fig.1 entlang der Schnittlinie II-II,

Fig.3 einen Querschnitt durch einen Fußbereich einer Turbinenschaufel nach Fig.1 entlang der Schnittlinie III-III,

Fig.4 einen Querschnitt durch einen Fußbereich einer Turbinenschaufel nach Fig.1 entlang der Schnittlinie IV-IV und

Fig.5 einen Querschnitt durch einen Fußbereich einer Turbinenschaufel nach Fig.1 entlang der Schnittlinie V-V.

An exemplary embodiment of the invention is given in the figures. Show it:

1 shows a radial cross section through a foot region of a turbine blade,

2 shows a longitudinal section through a foot region of a turbine blade according to FIG. 1 along the section line II-II,

3 shows a cross section through a foot region of a turbine blade according to FIG. 1 along the section line III-III,

4 shows a cross section through a foot region of a turbine blade according to FIG. 1 along the section line IV-IV and

5 shows a cross section through a foot region of a turbine blade according to FIG. 1 along the section line VV.

1 shows a radial cross section through a foot 4 and a platform 2 and part of a blade profile 1 a turbine blade. The foot 4 is in a holding recess 30 a turbine disk 3 and pushed by teeth 35 of the foot 4 and corresponding teeth 36 of the holding recess 30 held positively, as shown in Fig.2. Foot 4, platform 2 and profile 1 are in one piece, connected shaped, preferably cast. Juxtaposed Blade profiles 1 offer a hot gas flowing past Resistance and change its speed and direction, which causes the turbine disc 3 to rotate at a very high rate Speed is excited about a disk axis. The one here Centrifugal forces must essentially come from the teeth 35 of the blade root 4 and the teeth 36 of the holding recess 30 can be caught. Especially for indoor refrigerators Turbine blades are generally large parts of the turbine blade massively trained and therefore have a high Weight that puts a heavy load on the foot areas.

The foot 4 has a weight-reducing according to the invention Excavation 7 on. This is shaped like a vault and ends on Platform-side end 19 of the turbine blade blind below the top 21 of the platform 2. On a platform facing away from The end 7 of the foot 4, the cavity 7 is open. The Foot 4 has one in the region of the end 31 facing away from the platform essentially constant length 32. The length 32 takes when approaching platform 2, first because of a molding 37 of the transition area 38 something to then to Take off platform 2 continuously. The cavity 7 has lengths 13 of longitudinal walls 12 and depths 33.

The lengths 13 start from that facing away from the platform End 31 after a certain distance to the platform side End 19 of the foot 4 are in the transition area 38 in one arcuate shape shorter to the highest point with the Height 16 of the cavity 7, where the cavity 7 ends blindly. This end is preferably in the range or below Platform top 21 to ensure sufficient stability of the Ensure shovel. The blade profile is in the platform area massive and possibly has a weight-saving Blade profile cavity in the upper, not shown Area of the blade profile at a distance from the platform. This avoids the strength of the blade in the Endanger the platform area. The cavity 7 has none Connection to the blade profile cavity, since it is a internally uncooled turbine blade acts and therefore not Coolant transport through the foot is necessary.

The depth 33 decreases, as shown in Fig. 2, from the platform facing away End 31 of the foot 4 to the platform end 19 towards 5 in an area. Then the cavity 7 follows one Turning of the turbine blade in the transition area 38. The depth 33 initially increases somewhat in the transition area 38 in order to then from approximately the middle of the transition region 38 to Platform 2 to decrease steadily. This is the greatest possible Area within foot 4 or respectively Transitional area 38 hollowed out for maximum weight reduction to achieve. It is particularly taken into account that the walls 8, 12 sufficient wall thicknesses 14 for Ensuring the stability of the foot 4 even with strong ones attacking centrifugal forces. Due to the domed training the hollow 7 voltage peaks are avoided, the lead to a reduction in strength.

The hollow 7 can be produced by a casting core with lost shape, that in the foot area of the shovel is used before casting and over the platform facing away End 31 of the foot 4 protrudes, whereby a platform faces away forms open cavity. On the platform side End 19 of foot 4 is the casting core as the blind core ending there educated. After the casting, the core is destroyed and out the cavity 7 removed because it is due to the opening do not remove the narrowing width as a whole leaves.

Cross struts 28 are attached within the cavity 7, which run between the longitudinal walls 12. Through the cross struts 28 the cavity 7 becomes against attacking forces, which act on the walls 8, 12 supported. In the embodiment there are five cross struts 28, of which the Cross strut 28 in the central region 15 of the cavity 7 has the greatest height 20 and in the region of the greatest height 16 the cavity 7 is arranged. The cross struts 28 are rounded, to avoid voltage peaks. They are essentially parallel to each other at intervals 34 in the direction a longitudinal axis 39 of the turbine blade. you take almost the entire area between the two opposite Longitudinal walls 12 a. Only on the platform side and end of the cavity 7 facing away from the platform rounded, cross-strut-free areas with a distance of 40 to the upper limit of the cavity 7 and a distance 41 to the lower in the end facing away from the platform 31 Areas are essentially production related, because Cast iron fingers through which the material-free areas are produced between the cross struts 28, at the ends with each other connected in order to be able to maintain correct dimensions. In addition, they also contribute to further weight savings at.

Fig.2 shows a radial cross section in an almost right Angle to the first longitudinal section of Figure 1 along the Section line II-II. At regular intervals the foot 4 bulging teeth 35, the correspondingly shaped teeth 36 the holding recess 30 of the turbine disc 3, in which the foot 4 is used, reach behind and so a safe Positive locking against slipping out of the turbine blade Ensure centrifugal load. From the platform away End 31 to platform-side end 19 of the foot 4 takes one of the teeth 35 and intervening dents formed mean width 6 'of the foot 4 to. This middle one Width 6 'follows the depth 33 of the transverse region of the cavity 7 while maintaining minimum wall thicknesses that ensure stability of walls 12. The one following foot 4 Transition area 38 is curved like a lens, as in cross section is clear from Fig.4. Accordingly, the excavation is 7 shifted relative to their training in the foot 4 so that sufficient wall thicknesses 14 on both sides of the cavity 7 are guaranteed.

3 shows a cross section through the foot 4 along the Section line III-III from Fig. 1 and Fig. 2. The width 6 the cross section through the foot is quite large since the cut by an upper tooth 35 of the foot 4, that is in the area the greatest width 6 of the foot 4, runs. The excavation 7 consists in this section of several chambers 29, the Cross struts 28 partitions of the chambers 29 correspond. The Chambers 29 point from the two transverse walls 8 of the foot 4 starting from an increasing depth 33 that has its greatest extent at the central cross strut 28 in order to then again with an approach to the other transverse wall 8 of the foot 4 decrease. The boundaries of the chambers 29 are to be avoided rounded on all sides by voltage peaks.

4 shows a section along the section line IV-IV of FIG 1 and 2 through the transition area 38. The cavity 7 has only five chambers in this area 29 or four cross struts 28, since the Cut above the nearest hot gas upstream Cross strut is done. Thus is on the area of the hot gas inflow side 17 shows an enlarged chamber 29. The wall thickness 14 of the wall 8 is in the region of the hot gas inflow side 17 larger than in the opposite area of the hot gas outflow side 18. Through this adapted, slightly asymmetrical training the cavity 7 can be individually reinforced Tensions or attacking forces under optimal Weight saving intercepted to maintain strength become.

5 shows a section through the narrowest Area of the foot 4 along the section line V-V of Fig.1 or according to Fig. 2. The chambers 29 of the cavity 7 also have a cross wall 8 starting increasing cross-sectional depth 33, but the change in cross-section is not as great as in Fig. 3. The maximum is again in the area of the central cross strut 28

Claims (11)

Turbine rotor blade, with an internally uncooled blade profile (1) starting from a bucket platform (2) extends to which extends into a turbine disc (3) engaging blade root (4) connects its radial Cross section to the blade platform (2) towards an area (5) has increasing width (6 '), characterized in that that the blade root (4) faces away from a platform has open cavity (7), the platform side ends blindly and in the area (5) of increasing width (6 ') of the blade root (4) is widened in cross section. Turbine rotor blade according to claim 1, characterized in that that the cavity (7) in a transition area (38) between the blade root (4) and below a platform top (21) of the platform (2) ends. Turbine rotor blade according to claim 1 or 2, characterized in that that the cavity (7) is largely rounded Walls (8, 12) is limited and in arched form ends below the platform top (21). Turbine rotor blade according to claim 1 to 3, characterized in that that longitudinal walls (12) of the cavity (7) over almost the entire length (32) of the blade root (4) and transverse walls (8) over almost the entire width (6) of the Blade root (4) extend, the walls (8, 12) of the Excavation (7) sufficient stability in the event of a centrifugal attack guarantee. Turbine rotor blade according to one of claims 1 to 4, characterized characterized in that the cavity (7) in the middle Area (15) has the greatest height (16) and to the Transverse (8) and longitudinal walls (12) falls off. Turbine rotor blade according to one of claims 1 to 5, characterized characterized in that the longitudinal walls (12) of the Excavation (7) when approaching the platform end (19) with a minimum wall thickness (14) to the Transverse walls (8) of the cavity (7) steadily in some areas widen. Turbine rotor blade according to one of claims 1 to 6, characterized characterized in that the minimum wall thickness (14) in the Near a hot gas inflow side (17) is larger than that Hot gas outflow side (18). Turbine rotor blade according to one of claims 1 to 7, characterized characterized in that the blade root (4) from between its longitudinal walls (12) formed cross struts (28) is reinforced. Turbine blade according to one of claims 1 to 8, characterized characterized in that the cross struts (28) on the platform side from the walls (12) of the cavity (7) and / or from the End facing away from the platform (31) of the blade root (4) distance (40, 41). Turbine rotor blade according to one of claims 1 to 9, characterized characterized that positions and shapes of the cross struts (28) are adapted to a line of force that by centrifugal forces acting on the blade profile (1) arises. Turbine rotor blade according to one of claims 1 to 10, characterized in that the transverse struts (28) of the cavity (7) in the central area (15) the greatest height (20) have and a sloping course of the cavity (7) adjusted in height (20).

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