This invention relates to turbomachine rotors, and particularly rotors fitted with blades around their periphery, that are subjected to vibrational phenomena during operation of the turbomachine.
Bladed wheels of turbomachines have a practically cyclically symmetric structure. They are generally composed of a series of geometrically identical sectors, except for a tolerance related to manufacturing tolerances of their various components and their assembly.
Although tolerances generally used for manufacturing of bladed wheels are small, they have significant effects on the dynamics of the structure. Small geometric variations, for example due to manufacturing and assembly of parts, or small variations in properties of the material from which they are made such as their Young's modulus or their density, can lead to small variations in the natural resonant frequency from one blade to another.
These variations are denoted by the term mismatch and are very difficult to control; the expression “accidental mismatch” is used in this case. These small frequency variations from blade to blade are sufficient to make the structure non-symmetric. The wheel is said to be mismatched. A variation with a standard deviation of 0.5% of even less between the natural frequencies of blades is sufficient to make the wheel mismatched.
On a mismatched bladed wheel, it is found that the vibrational energy is located on one or a few blades instead of being distributed around the entire wheel. The consequence of this positioning is amplification of the forced response. This term refers to the vibrational response to an external excitation.
External excitation on a turbomachine, particularly an aeronautical machine, is usually caused by asymmetry in the aerodynamic flow. For example, it may be due to an upstream side stator or a downstream side stator, a distortion, taking off air in the compressor, reinjected air, the combustion chamber or the structural arms.
Blade to blade response levels may vary by a factor of 10 and the maximum on the bladed wheel may be twice or even three times as much as would have been obtained on the perfectly symmetric wheel.
The variation in the response to an excitation source as a function of the mismatch follows a curve like that shown in
The purpose of the invention is to introduce a deliberate mismatch on the bladed wheel so as to reduce the maximum response on the wheel, and no longer depend on the small accidental mismatch that is always present.
The method according to the invention to introduce a deliberate mismatch into a turbomachine bladed wheel so as to reduce vibration amplitudes of the wheel in forced response, is characterised by the fact that it consists of determining an optimum value of the mismatch as a function of operating conditions of the wheel in the said turbomachine, corresponding to a maximum required vibration amplitude response, and of at least partly placing blades with different natural frequencies on the said wheel such that the standard deviation of the frequency distribution of all blades is equal to at least the said mismatch value, the said mismatch value being determined by a statistical calculation method.
The standard deviation of the deliberate mismatch introduced is advantageously greater than this optimum value b.
The value b depends on the wheel being studied, the stiffness of the disk and the value of damping present on the bladed wheel. It can be considered that in most cases, the value of b is a standard deviation of the frequency of the order of 1 to 2%. In these cases, the typical deviation of the deliberate mismatch introduced is more than 2%.
The Campbell's diagram is intended to determine the frequency situation of the structure with regard to possible excitations. Frequencies of vibration modes of the bladed wheel as a function of the rotation speed of the wheel, and the possible excitation frequencies are shown on this diagram. Intersections between these two types of curves correspond to resonance.
One example excitation source consists of an upstream stator comprising N blades. The excitation with frequency f=Nω is monitored on the downstream side of the stator, where ω is the rotation frequency of the rotor. In the context of a turbomachine design, the geometric and structural parameters of the mobile wheel concerned are determined so as to shift resonance outside the operating range with a safety margin.
For example, consider the Campbell's diagram in
This resonance may not be acceptable, depending on the mode type.
Therefore, it is obvious that it is difficult to find an acceptable compromise.
For example, if it is required to improve the situation for the Mode 4/order N2 resonance, introducing a deliberate mismatch of b % will spread the frequencies of the bladed wheel about their average value. Instead of having one line per mode, there is one band per mode. The band width depends on the mode: a deliberate mismatch of b % for one frequency will not necessarily introduce a variation of b % in the other frequencies.
This is much more restrictive for the design since the possible resonance ranges are wider. For example in the previous case, modes 1 to 3 that respected the frequency margins in the matched case no longer respect them.
Therefore, the purpose of the invention is also to determine the minimum value b to have a significant effect on vibration amplitudes, while spreading structural modes as little as possible to facilitate the structure design.
With reference to
As mentioned above, the said mismatch value is determined using a statistical calculation method.
This method includes the following steps:
Another purpose of the invention is a bladed wheel with a deliberate mismatch.
A bladed wheel for which the deliberate mismatch was determined using the method according to the invention has blades with different natural frequencies, the number of different frequencies outside the manufacturing tolerances being not more than 3.
According to another characteristic, the blades are distributed in patterns with blades with natural frequency f1 and blades with natural frequency f2, where f2 is not equal to f1. In particular, successive patterns are identical, similar or have a slight variation from one pattern to another.
According to another characteristic, each pattern comprises (s1+s2) blades, s1 blades with frequency f1 and s2 blades with frequency f2. In particular, s1=s2 and s1 is not larger than the total number N of blades in the wheel divided by 4. In particular, each pattern comprises (s1+s2+/−1) blades including (s1+/−1) blades with frequency f1 and (s2+/−1) blades with frequency f2.
According to another characteristic, in which the wheel is subjected to a harmonic excitation n less than the number N of blades in the wheel divided by two (n<N/2), the blades are distributed in n identical patterns or with a slight variation from one pattern to the next.
According to another characteristic, in which the wheel is subjected to a harmonic excitation n greater than the number N of blades in the wheel divided by two (n>N/2), the number of patterns is equal to the number of diameters in the mode concerned.
The invention is described in more detail below with reference to the drawings in which:
We will now describe the statistical method used to determine the minimum value to be used for the mismatch in more detail as a function of the characteristics of the bladed wheel to be treated and limit the forced response to coincidence identified in the operating range.
During step 10, an initial value σj of the standard deviation of mismatch frequencies is chosen. For a bladed wheel 100 (
In step 20, a distribution Ri is digitally generated at random. For a predefined value of the standard deviation σj of a bladed wheel, there is an infinite number of distributions Ri of blades on the wheel MRi, and of natural frequencies of these blades satisfying this standard deviation condition σj.
In step 30, the determination for this distribution Ri is made using a known numeric method for calculating the amplitude response to an excitation. For example, for a turbojet compressor it could be a response to distortions in the incident flow resulting from cross-wind.
The response of each blade to the external disturbance for the wheel with distribution Ri is determined in this way. The maximum value Rimax σj is extracted in step 40, and is expressed with respect to the response obtained on a blade of a perfectly matched wheel. This value is more than 1, and is usually less than 3.
A loop back to step 20 is made in step 42 by determining a new distribution Ri+1, and the calculation is restarted to determine a new value Ri+1max σj. The calculations are repeated for number R of distributions. This number R is chosen as being statistically significant.
In step 50, the maximum Mσj of values Rimax σj is extracted for all R distributions. All values Rimax are used to determine the maximum amplification value that statistically would not be exceeded in more than a fixed percentage of cases, for example 99.99%. This result is achieved by marking the values on an accumulated probability curve. The scatter diagram is advantageously smoothed by a Weibull probability plot that reduces the number of required draws, for example to 150.
Thus, the point Mσj corresponding to a value of the standard deviation σj was determined on the diagram in
A new value σj+1 is fixed in step 52, and is used as a starting point for a loop back to step 10 to calculate a new value M σj+1.
In step 60, there is a sufficient number of points to plot the curve in
Once the curve in
The largest possible value of b could be chosen taking account of the shape of the curve beyond the maximum. However, the choice is limited by the fact that introducing a mismatch within the context of an improvement to the situation for a particular resonance is equivalent to widening the resonance ranges for other modes, as can be seen on the Campbell diagram in
According to another characteristic of the invention, it is checked that introducing a deliberate mismatch improves the aeroelastic stability of the wheel. The average of the damping coefficients corresponding to each possible phase angle between the blades is calculated, and it is checked that the mode concerned by floating is less than the said average.
In other words, if the engine test indicates that floating margins are insufficient, it might then be useful to introduce a deliberate mismatch.
The method includes the following steps:
In summary, the mismatch is optimised to minimise the forced response to resonance, assuring that the impact on the stability and the Campbell diagram (for other resonances) is acceptable, or the mismatch is optimised with regard to stability, while assuring that the impact on the Campbell diagram is acceptable.
The mismatch translates asymmetry of the structure. Therefore conventional analysis approaches with cyclic symmetry, in which only a single sector of the structure is modelled and the behaviour of the complete wheel is then reconstructed from this model, are not directly applicable.
Considering the asymmetry of the structure, a complete representation (360°) is necessary.
The simplest but also the most expensive approach is to model the complete structure; the size of the model then becomes enormous and difficult to manage, particularly using statistical mismatch approaches.
Therefore, a method has been developed to reduce the size of models. The simplified logic of this method is described below, knowing that many complexities also need to be taken into account, particularly related to the rotation speed:
A) The disk is assumed to have cyclic symmetry; a single disk sector is modelled. Calculations are made for all possible phase shift angles applicable to the boundaries of this sector.
For a bladed wheel with N blades, based on the principle of cyclic symmetry:
This provides a means of obtaining all modes of the symmetric disk.
B) For the blades, modes of a nominal blade isolated from the disk are calculated.
C) A mismatch vector is then introduced representing the variation in frequency from one blade to another, so as to disturb the modes of the nominal blade calculated in B) above.
D) The mismatched bladed wheel is then represented by a combination of disk modes calculated in A) above and the mismatched blade modes calculated in C) (projection on a representation base).
Steps A) and B) take a fairly long time to calculate but the calculation is only made once. However steps C) and D) are very fast, so that fast analyses can be carried out for different mismatch vectors. Therefore, this method is particularly suitable for statistical approaches.
As the number of modes calculated in steps A) and B) increases, the representation base also becomes broader and the result becomes more precise, but the calculation becomes more expensive.
For the forced response.
An aerodynamic force is calculated (non-stationary analysis). There are different methods. The calculation is fairly simple and inexpensive since it is decorrelated from the (mismatched) mode of the structure. A force calculation is sufficient, and this force is then applied to the mismatched structure derived from step D).
For stability.
This case is more complex because non-stationary aerodynamic forces depend on the mismatched mode. The “basic” aeroelastic forces are calculated for each mode in the representation base, for simplification reasons.
The total “mismatched” aeroelastic force is obtained by combining the “basic” forces according to the same superposition rule as that used in step D). (The representation base is the same).
Therefore, the stability calculation requires a large number of fairly expensive non-stationary aerodynamic calculations. On the other hand, mismatch analyses are very fast once the aeroelastic model has been built.
When the value of the mismatch to be introduced into the bladed wheel has been determined, this mismatch is advantageously done using one of the following methods.
Once the value of b has been determined, a distribution of blades on the wheel is selected for which the natural frequencies satisfy the standard deviation b condition.
Advantageously, all blades are positioned symmetrically on the disk, particularly in terms of angle, pitch and axial position. The wheel is asymmetric from the point of view of frequencies only.
Advantageously, the number of different types of blades is limited to two or three.
Consider that three types of blades are available with frequencies equal to f0, f1 and f2. For example, the nominal frequency of the blades is f0, the natural frequency of blades with a higher frequency than f0 is f1, and the natural frequency of blades with a lower frequency than f0 is f2.
According to a first embodiment, the blades are distributed according to the pattern [f1 f1 f1 f2 f2], giving a distribution f1 f1 f2 f2 f1 f1 f2 f2, etc.; on the rotor, there are two blades with frequency f1 alternating with two blades with frequency f2, or
according to pattern [f1 f1 f1 f2 f2 f2]; alternation with three blades, etc.
More generally, a pattern of (s1+s2) blades is defined using s1 blades with frequency f1 and s2 blades with frequency f2, repeatedly around the wheel. Even more generally, the successive patterns vary slightly from one pattern to the next, particularly by +/−1 blades or +/−2 blades. For example, 36 blades were distributed according to patterns (4f1 4f2) (5f1 5f2) (4f1 4f2) (5f1 5f2) or according to patterns ((4f1 5f2) (4f1 5f2) (5f1 5f2) (4f1 4f2). Other solutions would be possible.
According to one particular distribution method, s1=s2 and s1 is equal to not more than N/4.
Preferably, with the wheel being subjected to a harmonic n excitation, namely n disturbances per revolution, where n is less than the number N of blades in the wheel divided by two (n<N/2), the blades are arranged with a distribution that tends to have the same order of symmetry as excitation on the wheel. They are distributed in n identical groups, or groups with a distribution that varies little from one group to another.
In particular, if the number of blades is divisible by n, the blades are distributed into n repetitive frequency distribution patterns. Hence, for a wheel with 32 blades excited by 4 disturbances per revolution, blades may for example be arranged according to four identical patterns:
4 times the pattern f1 f1 f1 f1 f2 f2 f2 f2 or
4 times the pattern f2 f1 f1 f2 f2 f2 f1 f1 or
4 times the pattern f1 f1 f2 f2 f1 f1 f2 f2 or
4 times the pattern f1 f2 f2 f2 f2 f1 f1 f1.
Preferably, the average frequency is equal to f0 or is nearly equal to f0.
If the number N of blades is not divisible by the number n of disturbances, patterns are chosen that give a distribution that is as close as possible to a distribution in which N is divisible by n. Thus, for a 36-blade wheel excited by 5 disturbances per revolution, the blades are arranged according to approximately the same patterns: four groups of 7 blades and one group of 8 blades, for example such as (4f1 3f2) (3f1 4f2) (4f1 3f2) (3f1 4f2) and (4f1 4f2). Other distributions could be considered.
According to another embodiment, if the wheel is subjected to a harmonic n excitation, where n is greater than the number N of blades in the wheel divided by two (n>N/2), the blades are distributed around the wheel such that the number of repetitive patterns is equal to the number of diameters of the mode concerned. For example, 24 excitations per revolution on a 32-blade mobile wheel require a dynamic response from the so-called 8-diameter bladed wheel. Therefore, a mismatch distribution with 8 repetitive patterns is used.
There are various technological solutions for modifying the natural vibration frequency of a blade.
The frequency can be modified by varying the material from which the blade is made. This solution provides a means of making geometrically identical blades except for manufacturing tolerances and not modifying the steady aerodynamic flow. For example for metallic blades, the blade is made up from materials with different values of the Young's modulus or different densities. Since the frequencies are related to stiffness to mass ratio, simply changing the material has an impact on the frequencies. For composite blades, the texture of the composite in different zones is varied.
Another range of solutions consists of modifying the root of the blade without affecting the blade; the length or width of the stem, or the shape of the bottom of the blade overlength, or the thickness can be modified. In particular, isolated addition of masses under the blade overlength provides a means of offsetting the frequencies of the first vibration modes.
Other solutions apply to particular geometric modifications of the blade, for example: Hollowing the blade by micro-drilling and then reconstruction of the flowpath using a material with a variable stiffness or a variable mass.
Filling of cavities in hollow blades.
Use of local coatings such as thin ceramics so as to locally add mass in areas with a high deformation kinetic energy to offset the frequencies.
Local modification of the surface condition.
Modification of the blade head by machining a “cat's tongue”.
Modification of the blade head by machining a bath shaped cavity.
Modification of stacking laws for blade cuts along a direction perpendicular to its axis.
Use of blades with different lengths.
Modification of the blade/blade overlength connection at the fillet using different fillet radii. It should be noted that the impact on the first frequencies of the blade is significant, while the effect on the steady aerodynamic flow is limited.
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