To start from the end
and according to Mr. Bently [1];
Fact #1: Because the
Logarithmic Decrement presents the ratio of the two eigenvalue components, it
loses information. The Root Locus Plot is superior to the logarithmic decrement
because it displays both components of the eigenvalue. It allows us to see how
rapidly a particular eigenvalue approaches the instability threshold with
changes in either rotor speed or other parameters. At the same time, it allows
us to see how the natural frequencies of the system are changing.
Fact #2: The Campbell
Diagram presents only frequency information, and static frequency information
at that; it would be desirable to be able to see stability information on the
same plot. The Root Locus Plot presents eigenvalue data that represents both
stability and frequency information, and it shows how natural frequencies
change with rotor speed.
From the two above-mentioned
facts, following conclusions can be made;
- There are three methods for rotor system stability analysis; Logarithmic Decrement, Campbell Diagram and Root Locus Plot;
- The Root Locus Plot is the preferred rotor system stability analysis tool compared to the other two methods.
All the three methods are
reviewed here, in conjunction with the concept of stability (of a rotor system).
Stability
In terms of social and
human sciences, stability means “a situation in which things happen as they
should and there are no harmful changes” or more interestingly, “a condition in
which someone’s mind or emotional state is healthy” [5]. These definitions are
pretty much close to stability of a rotor system.
There are other
definitions of stability relating to being stationary or not moving or staying in
the same state, which is not true for a rotor system. The main characteristic
of a rotor is that it rotates!
For a rotor system,
particularly, there are a few different definitions of stability, all leading
to the same result;
- A mechanical system is unstable if, when it is disturbed, it tends to move away from the original equilibrium condition [1];
- A rotor system is unstable when the destabilizing forces exceed stabilizing (damping) forces [2].
Rotor System Model
Detailed derivation and solution
of rotor system model equations are beyond the scope of this article. Only a
summary is presented here with reference to [1].
Rotor system equation of
motion for free vibration is given by Equation (1). In this equation, M, D and
K are system mass, damping and stiffness and the term K-jDλΩ is the tangential
stiffness, in which λ is fluid circumferential average velocity ratio and Ω is
rotor speed.
Substituting r as
a general position vector solution in the form of Equation (2) into the
equation of motion leads to the characteristic equation of the rotor
system as presented by Equation (3).
Roots of the
characteristic equation are eigenvalues of the rotor system given by Equation
(4) and equation (5). Eigenvalue components, γ1, γ2 and ωd
are complicated functions of M, D, K, λ and Ω. γ is the growth/decay rate and ωd
is the undamped natural frequency.
The complete vibration
of the rotor system is given by Equation (6), consisting of r1,
the forward precession and r2, the reverse precession.
The growth/decay rate for
each eigenvalue can be calculated from Equation (7) and Equation (8).
Rotor Stability
Criteria
If the total vibration
is decaying, the rotor system is stable and if it is growing, the rotor system
is unstable (Figure 1). Growing and decaying of rotor system vibration is
examined by the growth/decay rate;
- γ < 0: The rotor system is stable;
- γ = 0: The rotor system is at the threshold of instability;
- γ < 0: The rotor system is unstable.
Figure 1: Vibration with
damped critical speed [3]
Logarithmic Decrement
Logarithmic Decrement has
a simple definition. It is the natural logarithm of the ratio of two
consecutive vibration peak amplitudes:
Based on this simple
definition, rotor stability criteria can be derived;
- If any vibration peak amplitude is smaller than its previous peak amplitude (An+1<An), that means the vibration is being damped or dissipated and rotor system is stable. Because the amplitudes ratio is bigger than 1, its natural logarithm is positive. Hence, rotor system stability is achieved when δ>0.
- If the vibration amplitude is growing in each time period (An+1>An), the rotor system will be unstable and with the amplitudes ratio smaller than 1, the natural logarithm will be negative. Therefore, rotor system is unstable when δ<0.
Logarithmic decrement
can be expressed in terms of the ratio of rotor system eigenvalue components [1];
This expression is
helpful in noticing the relationship between rotor stability criteria by
logarithmic decrement and by growth/decay rate. The negative sign denotes that
if γ<0, then δ>0 and rotor system is stable. Similarly, if γ>0, then
δ<0 and rotor system is unstable.
Campbell Diagram
The
Campbell Diagram is a representation of a rotating machinery (train) rotor
system natural frequencies or resonant speeds (on the vertical axis) versus all
the excitation frequencies or operating speeds of each individual rotor (on the
horizontal axis).
A
sample Campbell Diagram is shown in Figure 2. In this Campbell Diagram, both
lateral natural frequencies (solid lines) and torsional natural frequencies
(dotted lines) are included. The diagonal line denotes 1X or synchronous
vibration.
Figure
2: A sample Campbell Diagram
The Campbell
Diagram is to be used in the following way:
- Find the point of intersection of a horizontal line (or a natural frequency) with the 1X line;
- Ideally, no vertical line (or an excitation frequency) shall be in the vicinity of the point of intersection.
It is
recommended that 2X and 3X diagonal lines be shown on the Campbell Diagram as
well, and similar intersections be checked.
The
problem with the Campbell Diagram is that the natural frequencies shown by the
horizontal lines are associated with the situation that the machinery is at its
operating speed. The Campbell Diagram, while useful, represents an
oversimplification of rotor response [1];
- Many damped natural frequencies in a rotor system change with rotor speed;
- The Campbell Diagram presents only static frequency information;
- It would be desirable to be able to see stability information on the same plot.
Root
Locus Plot
It
can be seen from equation (7) and Equation (8) that the growth/decay rate is a
function of rotor speed. This is true for the other eigenvalue component,
damped natural frequency, too. This means that the vibration behavior of the
system changes with rotor speed [1].
The
Root Locus Plot is a representation of eigenvalue components, γ and ωd
on the horizontal and vertical axis of an XY diagram respectively (Figure 3).
Any point on the plot is associated with a specific rotor speed. Connecting all
the points, gives the root locus plot of the rotor system.
Figure
3: A sample Root Locus Plot [4]
From
the stability criteria, it is evident that the left half plane (γ<0) is the
stable operating region and the right half plane (γ>0) correspond to
unstable rotor system behavior. On the root locus plot, it is easy to follow
how the eigenvalues, and mainly the growth/decay rate, change with rotor speed
and which rotor speed corresponds to the threshold of instability.
For
the sample rotor system with the Root Locus Plot is shown in Figure 3, the
threshold of instability is 1050 rad/s (Figure 4) which is caused by the
forward precession. The further left on the plot that the root exists, the more
damping exists to control the decay rate of the rotor motion. The reverse root
poses no threat to the stability because it moves toward left of the plot [4].
Figure
4: The sample Root Locus Plot; forward precession [4]
At
this point, the two facts at the beginning of this article are worth reading
again.
References
[1]
Bently, Hatch, 2002, “Fundamentals of Rotating Machinery Diagnostics,” Bently
Pressurized Bearing Press.
[2]
Moore, “Rotordynamics Tutorial: Theory, Practical Applications and Case Studies,”
Southwest Research Institute.
[3]
Gunter, 2001, “INTRODUCTION TO ROTOR DYNAMICS - Critical Speed and Unbalance
Response Analysis,” RODYN Vibration Analysis, Inc.
[4]
Grant, 1999, “Root locus analysis – An excellent tool for rotating machine
design and analysis,” ORBIT Second/Third Quarters 1999.
[5] Macmillan
Dictionary, www.macmillandictionary.com.