DE3109519A1 - "VIBRATION DAMPED SHOVEL FOR TURBO MACHINES" - Google Patents

Description

FATBIiTAiTWAL, T. DIPL. ING. K. HOLZEE PHILIPPINE -WBIiSEB- 8ΤΒΔ88Β Ι *

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Augsburg, March 10th, 1981 Anw.Aktenz .: R.IO67

■ Rolls-Royce Limited, 65 Buckingham. Gate, London SWlE 6AT, England

Vibration-damped blade for turbo machinery

The invention relates to a vibration-damped blade for turbo machines according to the preamble of claim 1.

In the case of long compressor blades, for example the fan blades of a twin-flow gas turbine engine, so-called platform-like stabilizers are used, which are arranged in the course of the blade length on the blade and for damping torsional and flat vibrations serve the shovel. The stabilizers of the individual blades of a blade ring lie against one another in this way

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indicate that they together form a continuous ring and act sohwingungsdämpfend through their mutual friction. Such stabilizers, however, represent an undesirable additional weight, which is why the blade roots and the impeller disks or the impeller drums on which the blades are mounted must be considerably reinforced in order to be able to withstand the strong centrifugal forces acting on the stabilizers. Furthermore, the arrangement of stabilizers complicates the manufacturing and machining process of the blade, a deterioration in the aerodynamic efficiency of the blade and strong stress concentrations in unprotected areas of the blade. As a result, great efforts are made to avoid stabilizers whenever possible.

It is also already known to use turljiin blades with cover

to provide band segments, which propellant gas leakage flows in the Keep the blade tip area to a minimum and largely in the same way as the stabilizers of the compressor blade contribute to the damping of blade vibrations. Here, too, occur in the turbine rotors as a result of the at the blade tips arranged shroud segments again those already in connection with the stabilizers of compressor blades mentioned problems, which is why it is very important to dispense with the use of shroud segments and the problems

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the vibration damping and the sealing gap in the blade tip area to be treated separately.

Finally, it is already known to use blade vibrations in blades without shroud segments damping from elastic blocks placed under the footplate, but this requires a longer blade, in order to obtain sufficient flexibility for the effectiveness of the vibration damping. This in turn brings but greater loads on the impeller disc edge with it.

The invention is therefore based on the object of a

Another possibility for effective damping of blade vibrations that allows it to be placed on stabilizers, shroud segments or other known vibration dampers to renounce.

This object is achieved according to the invention by the arrangement specified in the characterizing part of claim 1 solved.

The arrangement according to the invention has the advantage that the vibration damper is arranged inside the blade and therefore the aerodynamic efficiency of the blade is not

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impaired. In addition, the construction of the vibration damper makes it possible to provide sufficient vibration damping to achieve without the blade or the rotor being loaded by excessive centrifugal forces. Also is a blade according to the invention easier to manufacture and process, and therefore more cost-effective to manufacture than conventional ones, with stabilizers or deekband segments provided blades.

The damping elements of both groups can each be wound through the turns of a helical spring be formed flexible component, the two, the two groups of damping elements forming components have the same incline and the same dangling sense and with theirs The coils are interlocking in the blade bore, so that the turns of the two components along two axially spaced apart helical lines Touch contact surfaces.

Alternatively, the two groups can each alternate a number of times with one another in the blade bore have arranged damping elements, wherein the Damping elements can each be designed as rings with a circular, triangular or trapezoidal cross-section can. The damping elements of the first group can also

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be designed as appropriately shaped disks. The ".-Die" are preferably the damping elements of the second group slotted forming rings. The cross-sections of each ring can be different.

The damping elements of the second group can each be ring-shaped and the damping elements of the first group each a convex surface (e.g. spheroid, obloid, Proloid or ellipsoid), which the two axially adjacent damping elements of the second group along ring-shaped contact surfaces, whereby the tangents, of the convex surface errs, the contact area is inclined with respect to the longitudinal axis of the bore.

The damping elements of the second group can through a plurality of balls be formed, which are spaced apart in the form of along the axis of the bore.

lying rings arranged on the bore wall are, and the damping elements of the first group are each between two adjacent ball races and stand in contact with these.

If the damping elements of both groups are each designed as rings with an approximately triangular cross-section, has each a corner of the triangular cross-section in the damping elements of the first group radially outward and in the

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Damping; elements of the second group stadial inward, and the damping elements of the first and second groups, which are arranged axially alternately with one another in the bore, touch each other on two triangle sides of the cross-section.

In a corresponding manner, the damping elements of the two groups can each take the form of rings with a trapezoidal shape Be formed cross-section, the trapezoidal cross-sections are oriented so that the narrow side in the damping elements of the first group radially outward and in the Damping 3 elements of the second group radially inwards

has and the damping elements of the two groups, respectively touch each other with their inclined trapezoidal surfaces.

Some embodiments of the invention are given below Described in more detail with reference to the attached [drawings, in which show:

Fig. 1. a turbine blade in longitudinal section

with a vibration damper according to the invention i

Fig. 2 in an enlarged representation

Section of the vibration damper according to Fig. 1, and

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the pig. 3i modified embodiments of the up to 8 'vibration damper.

Pig. 1 shows a turbine blade 10 for a gas turbine engine, which has an airfoil 11 with an airfoil profile and a blade root 12, the latter

in conventional? Pom is designed as a Christmas tree base and for holding dfer blade in a complementary profiled holding slot on the circumference of an impeller disk or rotor drum serves.

The blade is provided with a blind hole 13 running from the blade root in the longitudinal direction of the blade, which is cast or incorporated and its diameter typically Jim Breich is 6.0 mm. Of course however, the hole can be larger or smaller if necessary. A vibration damper 14 is located in the blade bore 13 arranged to dampen blade vibrations with any direction of wind relative to the axis of the bore serves,

The vibration damper Ik consists of two components 15 and 16 wound like a helical spring, which are wound in the same direction and have the same pitch. the

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Components 15 and 16 each have a substantially triangular cross-sectional shape. The overall diameter of the two nested components 15 and 16 is just slightly smaller than the diameter of the bore 13.

One of the components 15 has a corner of the triangular cross-section radially inwards and one side of the triangle of the cross-section is in contact with the wall of the bore. In the other component 16 has an E $ k dejs triangular cross-section radially outwards, and their turns lie in the spaces between them the turns of the first component 15. The turns the two components therefore form two groups of damping elements, each of which has a triangular cross-section and alternately point outwards and inwards with a triangular apex. The turns of the two components 15 and 16 to one another, the through two triangular sides of the triangular cross-section of each turn formed contact surfaces alternately after the are inclined one and the other direction with respect to the bore axis.

The component 16 has a slightly smaller diameter than the component 15, so that it is in the blade bore something can be moved sideways,

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If the blade, acting as a rod clamped on one side, bends during operation, the blade bore occurs 13 runs in the longitudinal direction of the blade, on one side of the bore axis an enlargement of the Winding distance of the component 15 and on the other Side of the Bohrtingsachse at the same time a compression of the turns of this component. This requires a certain lateral displacement of the component 16 located radially inside the component 15, whereby the axial movements of the turns of the component 15 are compensated. The in operation as a result of the circulation of the The impeller, which carries the blade, on the components 15 and l6 acting centrifugal forces have the consequence that these two Components are urged against the closed end of the blind hole 13 and compressed, so that the component in full contact with the component 15 and this is urged radially outward against the bore wall. The friction between the two adjacent components 15 and 16 during transverse movements' of the component 16 has a damping of Blade vibrations result.

The two components wound like a helical spring 15 and 16 can through the outer hose one under the brand "Bowdenex" available Bowden cable be formed.

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lit:

1 ^ ·

Bowdenex cables are used as transmission organs in Applications in which changes in the mean length of the core rope relative to the outer tube due to bends of the Bowden cable are not permitted. The outer hose of a Bowdenex Bowden cable consists of two helical lines winding components, one of which has a triangular -ν cross-section with a triangular tip pointing radially inward and the other component of which has a circular cross-section. It has been shown that such a Outer hose for the production of the! [Vibration damper of the blade according to the invention is useful.

There are other cross-sectional shapes of the components

i and 16 possible. For example, the cross-section according to Pig. 3 be approximately trapezoidal with two trapezoidal sides converging to one another. In this case are ^; the two components 16 and 16 are arranged so that the trapezoidal cross-sections of the intermeshing turns point alternately with their narrow side outwards and inwards. The surfaces in contact with one another, namely the converging trapezoidal surfaces of the intermeshing turns, are in turn inclined alternately to one side and to the other with respect to the longitudinal axis of the bore.

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The cross-sections of the components 15 and 16 can according to Pig. 4 also each be circular, and in this In this case, the tangents of the cross-sections at the points of contact of the intermeshing turns are alternating the one and the other direction inclined to the bore axis.

It is also possible to use the two components 15 and 16 train with different cross-sectional shapes. For example, one component can have a triangular cross-section have, while the other component has a trapezoidal cross-section, all that matters is that the two Components 15 and 16 each touch so that the contact surfaces alternately after the one and after run inclined in the other direction to the bore axis.

If desired, the one-piece, helical winding components 15 and, according to FIGS. 1 to 4, can also be replaced by groups of damping elements arranged along the bore. Embodiments of such Vibration dampers are shown in FIGS.

According to FIG. 6, the elements of both groups 15 and 16 designed as rings, each with a triangular cross-section, which are arranged alternately in the bore, so that one

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an arrangement similar to FIG. 2 is obtained. Each ring is 15 radially slotted so that it can be stretched in the bore. The rings 16 are provided with closed radial slots and have a slightly smaller outer diameter than the bore so that they can move transversely in the bore. The rings 15 and 16 can also be circular or trapezoidal cross-sections, as in Figs. 5 and is shown.

Other cross-sectional shapes are also possible. Need it not both groups of elements each have the same shape, provided that the damping elements 16 are free in the Bore are transversely movable and rest with the damping elements 15 on contact surfaces, which alternately after the one and are inclined in the other direction with respect to the bore axis.

In the embodiment according to FIG. 8, the component 15 of the embodiments shown in FIGS. 1 to 4 is provided with a number of individual slotted rings replaced circular cross-section, which are arranged at mutual intervals along the bore 13, and the Component 16 of the exemplary embodiments according to FIGS. 1 to 3 is replaced by a number of balls, the latter also being Solid of revolution with obloid, proloid or ellipsoid

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- γ- φ

Can be surface. The balls 16 are freely transversely movable and are each with the two axially adjacent rings along annular contact lines in contact, the Tangents of the ring cross-section at the points of contact in turn are inclined alternately in one direction and in the other direction with respect to the bore axis.

In all the exemplary embodiments described above, the two components 15 and 16 or the elements are in contact of the two groups 15 and 16 to each other at contact surfaces that alternate along the longitudinal axis of the bore after the one and are inclined in the opposite direction with respect to the axis of the bore. This means that the elements 16 each lie in conical recesses between the elements 15, from which, when the blade bends, the respective Element is displaced sideways. It also causes relative rotation of a cross-section of the bore with respect to one another on a further cross-section axially removed therefrom, a sliding movement of the elements 15 and 16 on one another and on the bore wall. The centrifugal forces acting on the elements or components and 16 tighten them together and occur Shovel vibrations are dampened by the Vibration energy in the form of friction between the contact surfaces of the elements or components 15 and 16 is consumed will.

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If the elements 15 are designed as separate rings, they are radially slotted so that they fit into the bore can be used and expand radially under the effect of centrifugal force in frictional engagement with the bore wall can.

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Claims (13)

Claims y Vibration-damped blade for turbo machinery, consisting of an airfoil-shaped airfoil and a blade root, characterized in that a) the blade one from the blade root in the blade longitudinal direction bore running towards the blade tip and a vibration damper arranged in this bore having, b) the vibration damper consists of two groups of damping elements (15, 16), of which the damping elements (16) of the first group are within the blade bore (13) transversely movable and the damping elements (15) of the second group each in frictional contact stand with the wall of the hole, c) the damping elements of the first group (16) and the second group (15) each bear against one another at two contact points lying apart in the longitudinal direction of the blade bore (13), the contact surfaces the damping elements at one point of contact i. a sense of direction with respect to the axis of the bore in the 130052/0787 inclined and at the other point of contact in the opposite direction of contact to the bore axis run inclined, such that when the blade bends, the resulting inclination movements of the damping elements (15) of the second Group by transverse movements of the damping elements (16) of the first group are compensated and vibrations are dampened by friction. 2. Shovel according to claim 1, characterized in that the second group has only a single damping element (15) and cooperates with a number of damping elements (16) of the first group which are spaced apart from one another are arranged along the blade bore (13), wherein each damping element (16) of the first group is the only damping element (15) of the second group in two with axial spacing longitudinally the blade bore (13) touches apart points of contact, 3. shovel according to claim 1, characterized in that the first group a plurality of mutually spaced damping elements (16) arranged along the shovel bore (13) and the second group a plurality of each 15ÖG52 / 0787 axially between two adjacent damping elements of the first Group arranged damping elements (15) comprises. 4 * shovel according to claim 1, characterized in that the damping elements of both groups (15, 16) through the individual turns of two coiled springs flexible components are formed, which are formed with the same pitch and the same winding direction and in such a way into one another are arranged that the turns of the [a component each lie between the turns of the other component and the turns of the two components are along two touch the helical contact areas. 5. A shovel according to claim 3, characterized in that the damping elements (15) of the second _; Group are each ring-shaped and the damping elements (.16) of the first group 'each have a convex surface with which they the two adjacent damping elements | l5) of the second group along ring-shaped contact surfaces [touch. 6. A shovel according to claim 5, characterized in that the damping elements (16) of the first group are each spherical are. 13ÖÖ52 / 0787 7. Shovel according to one of claims 1 to 5, characterized characterized in that the damping elements (16) of the first Group each have a circular cross-section. 8. Blade according to one of claims 1 to 4, characterized marked; that the damping elements (16) of the first group each have a triangular cross-section. 9. Shovel according to one of claims 1 to 4, characterized in that the damping elements (16) of the first Group each have a trapezoidal cross-section. 10. Shovel according to one of claims 1 to 9, characterized in that the damping elements (15) of the second Group each have a circular cross-section. 11. Shovel n & ch one of claims 1 to 9 »thereby marked! that the damping ungs elements (15) of the second group each have a triangular cross-section. 12. Shovel according to one of claims 1 to 9, characterized in that the damping te learn (1-5) of the second Group each have a trapezoidal cross-section. 190052/0787 13. Shovel according to one of claims 1 to 5 »characterized in that the damping elements of the first group (16) and the damping elements of the second group (15) each have a substantially triangular cross-section, one corner of the triangular cross-section in the damping elements of the first Group (16) faces radially outwards and in the case of the damping elements (15) of the second group points radially inwards and the mutually alternating damping elements of the first and second groups each ^{abut one another with:} two triangular sides. 130052/0787