Abstract
This paper proposes a mathematical model of the multirotor system with a flexible coupling on spring supports on Lagrange's approach, which has taken into account the effects of dynamic angular misalignment and mass unbalance. Then its nonlinear dynamic behaviors of the system are discussed based on the method of multiple scales and numerical technique, respectively. The results show that the responses of the system in lateral directions contain a similar component to that of the mass unbalanced system on both the vibrating frequency and amplitude and involve the typical nonlinear components such as the ones from some combined frequencies; the results also reveal that the numerical agreements on the above-mentioned methods are perfect for the transient responses.
1. Introduction
The misalignment of rotor system is one of the most common mechanical faults in rotating machinery, which can cause excessive vibrations, produce bothering noises, and create damaging forces on rotors, bearings, and couplings. For large-scale rotating system, there are several reasons that lead to the misalignments such as the various deformations of rotors, uncoaxiality of bearings and couplings. According to the geometric relationship between the two rotors, the types of misalignment may be divided into the parallel and angle ones or their combination. In practical engineering, generally the misalignment appears in some main form, for example, the ground subsidence or looseness and improper assembly of the rotor system can induce the faults of angle misalignment. In fact, even a multirotor system is well aligned in static equilibrium state; it still presents the dynamic misalignment or offset in a rotor system which couples by a flexible coupling.
During the past decades, the dynamics of effects on the rotor misalignments has been studied in a variety of aspects, that is, firstly Gibbons [1] established a model to predict the additional forces due to the misalignment of the gear coupling, Dewell and Mitchell [2] analyzed the lateral vibration frequencies for a misaligned rotor system which were based on the experiment, and Li and Yu [3] discussed the coupled lateral and torsional vibration of a rotor-bearing system with the misalignment by a gear coupling. In paper [4], Al-Hussain and Redmond studied the effect of parallel misalignment on the lateral and torsional responses of two-rotor system, and in [5], Al-Hussain considered the effect of angular misalignment on the stability of rotors connected by a flexible mechanical coupling. Prabhakar et al. [6] dealt with the transient responses of a rotor system with a rotor misalignment by using the finite element method. Recently, Hili et al. [7] established a linear dynamic model of a multirotor system which couples a Cardan joint by using the finite element method, in which both of the faults misalignment and unbalance were considered. Lees [8] studied the misalignment of a rigidly coupled rotor which mounted on idealized linear bearings with a linear time-varying stiffness. Li [9] developed a mathematical model of a multirotor system by taking into account the effects of parallel misalignment and unbalance of rotors, in which the misalignment was dealt with as a holonomic constraint, and Slim et al. [10] paid attention to the dynamic behaviors of misaligned rotor system mounted on two journal bearings. Patel and Darpe [11] investigated vibrating responses of misaligned rotors modeled by using Timoshenko beam elements with six degrees of freedom, and in paper [12], they studied the frequency spectra of the system supported on rolling element bearings by experiment. In 2010, Redmond [13] developed a dynamic modal of misaligned shafts, which included both the static angular and parallel misalignment.
For the multirotor system, flexible couplings are commonly used to transmit torque from one rotor to another when the adjacent shafts are slightly misaligned. And yet it is required coaxially during the installation for avoiding the additional forces on bearings, for example, the force is not permitted to be produced for a flexible coupling under static conditions; however, it is aligned or coaxial in this state, the coupling still appears a dynamic misalignment at work [14], that is, a dynamic angular deformation is generated on the flexible coupling duo to the dynamic load. In the above discussions, while much work has been done on the dynamics of the system that an initial or static misalignment exists, the little attention has been paid to the dynamic one. Accordingly, the purpose of the present paper is to explain the vibration mechanism and dynamic characteristics of rotor system with a flexible coupling after considering the effect on the dynamic angular misalignment.
2. Motion Equations
The proposed model of the multirotor system connected by a flexible coupling is shown in Figure 1, in which and denote the lumped masses, respectively; and represent the stiffness of the bearings; is the equivalent angular stiffness for the flexible couple. For simplification, the following assumptions upon the system of concern will be used hereinafter: (1) the two rotors are rigid; (2) the bearings are isotropic on dynamic performances; (3) the misaligned angle between the adjacent rotors is small.
The coordinate system is set up in the static equilibrium position of rotor system as shown in Figure 1. Let and be the coordinates of the mass centers of disc 1 and disc 2, respectively, then they yield where and are the displacements of disc 1 at the geometric center ; is the angle between adjacent rotors; is the rotating speed; is the initial phase angle; is the rotor length; , are the mass unbalances. If the generalized coordinates , , and are introduced, then (2.2) describes a nonstationary holonomic constraint because the displacement varies with time . Generally, the offset of disc 2 is larger than ; therefore, the terms related to are ignored in the paper.
The kinetic energy of the system can be written as and the potential energy is For simplifying the representation furthermore, let , and , then substituting (2.1) and (2.2) into (2.3) and (2.4), and based on Lagrangeβs equation the motion equation in the generalized coordinates becomes The above equations are second-order ordinary differential ones with variable coefficients, which is obviously the characteristic of strong nonlinearity. Based on the theory of differential equations, it is difficult to solve. By applying the inverse operation, (2.6) can be expressed as Let , be the nondimensional displacements, in which is the radius of rotor; , are the nondimensional mass eccentricity and rotor length, respectively; is the nondimensional time; , are the nondimensional angular frequencies and denote β¦; accordingly, (2.7) can be cast into the following nondimensional form:
Equation (2.8) is a parametrically excited system with three degrees of freedom on the theory of nonlinear vibration, in which and are the frequency ratios, respectively; Ξ΅is the nondimensional mass eccentricity is the nondimensional length. In the above equation, the third one is decoupled with the first two equations, that is, the generalized coordinate ΞΈ is totally independent of and Y thereby it can be solved in the first place.
In the case of the initial angular misalignment, it can be assumed that in which is the constant angle and is its perturbation. After substituting into (2.8) and expanding the relevant terms in the Taylor series, after neglecting the higher-order ones the governing equations that is of the initial or static angular misalignment between two rotors are obtained
3. The Approximation Solution
For discussing the vibration mechanism and characteristics of the system conveniently, let , namely, the initial or static angular misalignment of a flexible coupling vanishes, and only the dynamic angular misalignment presents in the system, then (2.9) reduces to The third of (3.1) is uncoupled with the first two; therefore, it can be simplified as where , .
The method of multiple scales (MMSs) is introduced for the approximation solution of the nonlinear vibration in this work. For the small angle , let and expand and [15] as where Ξ΅ stands for a small nondimensional parameter characterizing the amplitude of the motion. The term is missing from (3.3) because the nonlinearity appears at . The term is absent from (3.4) because the frequency is independent of the sign of Ξ΅. Substituting (3.3) and (3.4) into (3.2) and equating coefficients of like powers of Ξ΅, after donating , it yields The solution of (3.5) is of the form where and are constants; hence, (3.6) becomes Eliminating the secular term in (3.8) gives , then disregarding the solution of the homogeneous equation, its solution reduces to From the equation , it follows that in which , . If imposing the initial conditions and , then the constants and are obtained When , yields In practice, is small, thus the solution becomes . For example, if the parameters and , 0.05, the errors between them can be neglected at all. The numerical results are shown in Figure 2, which indicate a good agreements under the concerned parameters.
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Generally for the above nonlinear equations, there are six real solutions, in which the root is only satisfied for small oscillation in engineering, that is, the systematic parameters are considered as , , , and , accordingly, and after solving (3.11) on Maple, the six real roots of (3.12) are
The proves that, is an available approximate solution, , and are not almost changed with increasing the parameters and , which are not suitable for the engineering. Thereby, the former will be paid more attention to the following analysis, then expression (3.10) leads to Substituting expression (3.14) into (3.1), it yields and its general solution gives where , and are the constants.
If the initial conditions and are introduced, the constants , and can be determined easily; therefore, the responses can be shown to reduce to in which , and .
The above solution shows that the response consists of the following components: (a) the free vibration at natural frequency of the derived linear system. If the damping is concerned in and direction, its amplitude will be decreased exponentially on the theory of vibration; (b) forced vibration excited by the mass unbalance at the frequency of rotating speed. When , that is, the rotating speed coincides with the lateral natural frequency, the bending resonance of rotor system occurs; (c) the angular motions due to the flexible coupling, in which the frequencies and are combined by and the rotating speed. It is a typical nonlinear oscillation because the combination resonances exist atand.
Certainly, it should be noted that the above solution only reveals some dynamic behaviors of the rotor system connected to a flexible coupling, and some other characteristics such as the subharmonic resonances may be emerged if suitable conditions are satisfied.
4. Numerical Analysis
Because (2.8) is a strongly nonlinear system, the numerical technique is preferable. Accordingly, the Runge-Kutta method is carried out to predict the dynamic characteristics in the present paper. As a nonautonomous system, traditionally (2.8) is discussed on the state space, and hence the three second-order equations can be converted easily to six first-order ones
For the following calculation, the values of systematic parameters are considered as , , and , and all the initial generalized displacements and velocities are set to zero.
Figures 3(a) and 4(a) depict the displacement responses of rotor system in and directions when, respectively, in which the curves are demonstrated by using MMS and the numerical technique. The results show that the agreements between their responses are pretty almost at each interval, and thereby it proves that the dynamic behaviors of the system are in the form of (3.17) under certain initial conditions. Figures 3(b) and 4(b) appear as the frequency spectra of displacement responses by the numerical method, in which there are mainly four components from the vibrating frequencies:,, , and . Actually, it reveals that the synchronous motion emerges in the responses, which are obviously from the mass unbalance, and is the natural frequency of the derived linear system as shown in (3.15), and are the combinations between and the rotating speed , which occur frequently for a nonlinear system. Figures 5 and 6 also show the relevant responses and the spectra when . Figures 7 and 8 illustrate the responses and their spectra when, and , , namely, the angular stiffness of flexible coupling increases these vibration characteristics display the multifrequency signatures in the rotor system connected a flexible coupling with a dynamic angular misalignment.
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5. Conclusions
The misalignment of rotor system is an important reason which causes mechanical vibration; a dynamic misalignment or offset of the rotors can be produced at work even the system is aligned under the static conditions. In this paper, firstly a mathematic model of the multirotor system with a flexible coupling is established after considering the effect on a dynamic angular misalignment based on Lagrangeβs equation, and it shows that the system is of a parametric oscillation with strongly nonlinear characteristics. Then, the method of multiple scales and Runge-Kutta numerical technique are carried out, respectively. And the results indicate that the responses in lateral direction consist of some parts, that is, the synchronous vibration due to the mass unbalance, the free vibration at natural frequency of the derived linear system, and the angular motions caused by the flexible coupling at the combined frequencies.
Acknowledgment
The author acknowledges the financial support from the National Natural Science Foundation of China, China (Grant no. 11072190).