Fig. 1 illustrates a typical rotary axial ECD, comprising two primary components: the ball screw assembly and the eddy current damping generator. The ball screw assembly comprises a ball screw drive pair, a stator and a rotor in which the stator and the rotor are made from ferromagnet materials. On the other hand, the eddy current damping generator is composed of permanent magnets and a conductive cylinder, arranged on the rotor and the stator, respectively.

ECD is a kind of velocity-dependent nonlinear damper. At this stage, its constitutive behavior, namely the damping force-velocity relationship, is often characterized by the Wouterse constitutive model as follows:

(1)FECD=Fmax2vvcr+vcrvwhere FECD is the damping force of the ECD; v is the relative velocity between the two ends of the ECD; Fmax is the maximum damping force, and the vcr is the critical relative velocity when the damping force reaches its maximum value. The relationship curve of Eq. (1) is presented in Fig. 2. The two mechanical model parameters Fmax and vcr in the Wouterse constitutive model expression possess clear physical interpretations, facilitating researchers’ comprehension of the model.

Nevertheless, the Wouterse constitutive model expression differs from the power law constitutive model commonly used to simulate the mechanical properties of viscous dampers. The constitutive model of a nonlinear viscous damper can be expressed as

(2)FVD=cvαwhere FVD is the damping force of the viscous damper, c is the damping coefficient, and α is the velocity exponent. The constitutive model of viscous damper, namely a typical power law constitutive model, is widely supported by FEA software directly. On the contrary, only a few FEA software currently support the direct simulation of the Wouterse constitutive model for ECDs. Therefore, the development of a novel power law constitutive model specifically tailored for ECDs is crucial to achieving highly efficient performance in finite element analysis.

In order to improve the efficiency of FEM analysis with ECDs, we constructed a power law constitutive model as same as the one of viscous dampers. The parameters Fmax and vcr of the Wouterse constitutive model are retained for keeping its easily understandable characteristics.

A normalization process is conducted to retain the parameters Fmax and vcr. The dimensionless velocity x=v/vcr and dimensionless damping force y=FECD/Fmax was defined as the independent variable and dependent variable, respectively. Assuming the nonlinear damping behavior can be expressed by a series of power law functions. Therefore, the power law constitutive behavior model can be written as follows:

(3)yn(x)=a1x1+a2x2+⋯+aixi(i=1,2,⋯,n;x∈[0,+∞])where x is the dimensionless velocity; yn(x) is the dimensionless damping force; a=[a1,a2,⋯,ai] are constant parameters, and i is the number of the terms of the power law function.

A curve fitting method is employed to determine the values of the constants a in Eq. (3), aiming to accurately match the nonlinear constitutive behavior of ECDs. The numerical results obtained from electromagnetic finite element simulation are utilized as the target for the curve fitting process. In this study, the target curve is defined as y0(x). The electromagnetic finite element simulation was conducted utilizing the electromagnetic finite element analysis software COMSOL. In order to improve computational efficiency, the 3D model has been simplified into a 2D model. The schematic of finite element meshing is presented in Fig. 3.

The electromagnetic finite element analysis results are shown in Table 1.

Additionally, to ensure the mechanical properties of parameters Fmax and vcr, a constraint condition is applied, where the maximum dimensionless damping force is positioned at (1, 1). The above optimization problem can be formulated as follows:

(4){find:a=[a1,a2,⋯,ai]minimize:∑l=1m(y0(xl)−yn(xl))2s.t.:yn(1)=1;y˙n(1)=0where ∑l=1m(y0(xl)−yn(xl))2 is the objective function chosen as the sum of squares of the difference between the target curve and Eq. (3) at each dimensionless velocity. It is noteworthy that the number of the terms of the power law function in Eq. (3) is set to 4. To achieve better accuracy, we conducted the optimization process within the dimensionless velocity range from 0 to 1.5, which covers the most common operating velocity range of ECDs

Genetic algorithm is employed to solve the optimization problem. The expression of the power law constitutive model for the constitutive behavior of ECD was obtained as follows:

(5)y4(x)=0.184x4−0.122x3−1.309x2+2.247x(x∈[0,1.5])

The power law constitutive model damping force-velocity relationship curve is plotted in Fig. 4, and the Wouterse constitutive model relationship curve also is fitted and presented in Fig. 4 for comparison. It can be observed that the power law constitutive behavior model matches considerably well with the target curve. The coefficient of determination (denoted R², normally ranges from 0 to 1) is employed to assess the degree of agreement for two curves. The more closely the two curves match, the closer the value of R² is to one. The R-square value of the Wouterse constitutive model for FEM data in Fig. 4 is 0.9995, which indicates a hiah-level coincidence of the power law constitutive model for the constitutive behavior of ECD.

Substitute x=v/vcr and y=FECD/Fmax into Eq. (5) and consider the negative velocity, it can be written as

(6)FECD=sgn(v)Fmax[0.184vcr4|v|4−0.122vcr3|v|3−1.309vcr2|v|2+2.247vcr|v|](v/vcr∈[−1.5,1.5])

It can be observed from Eq. (6) that the power law constitutive model is still determined by the parameters Fmax and vcr as same as the Wouterse constitutive model. The nonlinear damping behavior of ECDs is expressed by the sum of four power law functions which are commonly used to characterize the mechanical behavior of viscous dampers in FEA software.

In conclusion, the power law constitutive model was demonstrated to be able to express the nonlinear damping behavior of ECDs. The parameters Fmax and vcr are retained for keeping its easily understandable characteristics. However, further validation is essential in order to confirm the accuracy of the power law constitutive model.

A mechanical property test was performed on the rotary axial ECD, as depicted in Fig. 5. The ECD was integrated into a dynamic test system, with one end fixed and the other end connected to an actuator. The test involved subjecting the ECD to sinusoidal displacement excitations at various amplitudes and frequencies. This study encompassed a total of nine cases, each with different displacement amplitudes and frequencies.

As shown in Fig. 6a, the damping force amplitude and the corresponding velocity amplitude of each case were recorded as circle marker. The fitted curve of the power law constitutive model was obtained and presented in Fig. 6a, and the curve of Wouterse constitutive model was also plotted as a comparison. The R-square value of the power law constitutive model for test data is 0.9932, while the R-square value of the Wouterse constitutive model for test data is 0.9901. This suggests that the power law constitutive model characterizes the nonlinear damping behavior of ECD properly. Furthermore, the hysteresis loops of the case with the velocity amplitude 60 mm/s are presented in Fig. 6b. It can be seen that the hysteresis loops directly obtained from the Eq. (6) match very well with the one recorded in the mechanical property test.

The mechanical property test results indicate that the power law constitutive behavior model can reflect the nonlinear damping performance of ECD accurately.

A linear elastic SDOF system supplemented with a nonlinear ECD subjected to ground motion is proposed to validate the accuracy of the power law constitutive model in numerical analysis. The schematic is plotted in Fig. 7. The motion governing equation of the SDOF-ECD system can be written as

(7)mu¨+cu˙+ku+fECD(u˙)=−mu¨gwhere m, k, and c are the mass, elastic stiffness, and linear viscous damping coefficient, respectively. u¨,u˙,u is the acceleration, velocity, and displacement, respectively. fECD(u˙) is the nonlinear damping force of the ECD. The system parameters are as follows: the mass m = 1000 kg; the natural frequency fn = 0.1 Hz; the damping ratio ξ = 0.02.

The Elcentro wave presented in Fig. 8 was adopted as seismic excitation in this section. The peak ground acceleration was taken to 2 m/s². The dynamic analysis was conducted utilizing the Runge-Kutta algorithm in the numerical analysis software Matlab. The dynamic response of the power law constitutive model was obtained and compared with the response of the Wouterse constitutive model.

It is noteworthy that the curve fitting process of the power law constitutive model was conducted with the dimensionless velocity x=v/vcr ranging from 0 to 1.5. The critical velocity vcr should be greater than 0.667vmax to meet this prerequisite. Therefore, As long as the critical velocity vcr is greater than 0.667 times the velocity response amplitude u˙max, the accuracy of the power law constitutive model can be guaranteed. Actually, for the purpose of achieving a better energy dissipation performance, researchers usually adopt a strategy that takes the value of the parameter vcr closing to the velocity response amplitude in engineering applications.

In this example, the parameter vcr is equal to the velocity response amplitude u˙max, and the velocity response amplitude is 0.224 m/s which is obtained without dampers installed in the SDOF system. The maximum damping force Fmax was taken to 200 N. The displacement response of the SDOF-ECD system and the corresponding hysteresis loops are plotted in Fig. 9. The coefficient of determination, namely the R-square value, of the two curves in Fig. 9a is 0.9975. It indicates that the displacement response curve of the power law constitutive model matches well with the one of the Wouterse constitutive model. Meanwhile, it can be observed that the ECD hysteresis loops of the power law constitutive model are consistent with the one of Wouterse constitutive model in nonlinear damping characteristics simulation.

In conclusion, the power law constitutive model is proved to be capable to characterize the nonlinear damping behavior of ECD accurately based on the test and numerical validation.

The simulation of power law constitutive model of ECD can be directly conducted using one of the existing elements, making it a straightforward process. However, utilizing the Wouterse constitutive model in ANSYS proves to be considerably more complex. Customization becomes necessary for implementing the Wouterse constitutive model, as depicted in Fig. 10. This customization involves configuring the FORTRAN environment and modifying the User Programmable Features (UPFs), which demands significant time and effort. Additionally, since many FEA software do not provide open access for customization, the Wouterse constitutive model cannot be effectively utilized in ECD finite element analysis.

The Combin37 element in ANSYS was adopted to simulate the power law constitutive model of ECD. This element is commonly used to simulate the damping behavior of viscous dampers. When the key option 9 of the Combin37 was taken to 0, the RVMOD formula of the element can be expressed as

(8)RVMOD=RVAL+C1|CPAR|C2+C3|CPAR|C4where CPAR is the control parameter which was set to velocity, RVAL is the linear damping coefficient which is taken to 0 when simulating the nonlinear ECD, and C₁~C₄ are real constants for controlling nonlinear behavior. Take the simulation of the nonlinear damping behavior of viscous dampers for example. When the real constants C₁~C₄ are set to cd, α−1, 0, 0, respectively, the simulation of the viscous damper is achieved. The parameter cd and α are the damping coefficient and the velocity exponent of the viscous damper, respectively.

Apparently, the power law constitutive model can characterize the nonlinear damping behavior of ECD successfully for sharing the same form of expression with the constitutive model of the viscous damper. Two Combin37 elements are adopted to simulate the mechanical property of ECD. According to Eq. (6), the real constants C1a,C2a,C3a,C4a and C1b,C2b,C3b,C4b of the RVMOD can be expressed as

(9){C1a=0.184Fmax/vcr4,C2a=3C3a=−0.122Fmax/vcr3,C4a=2

(10){C1b=−1.309Fmax/vcr2,C2b=1C3b=2.247Fmax/vcr1,C4b=0

By connecting two Combin37 elements in parallel, we can realize the simulation of the power law constitutive model of ECD. Thus, The damping behavior of ECD can be characterized conveniently and efficiently in FEA software.

In this section, we present an example of an SDOF system model. The seismic response of the SDOF system was obtained using ANSYS and compared with the numerical results obtained using the Runge-Kutta method. Through this comparison, the accuracy of the power law constitutive model for ECDs is confirmed, validating its effectiveness in predicting the seismic response of the system.

The same SDOF system in Fig. 7 was established in ANSYS. The seismic response analysis was conducted considering the SDOF system subjected to the Elcentro wave of Fig. 8. The displacement history curve is plotted in Fig. 11. The green dash-dot line represents the displacement response obtained by FEM, and the red dashed line represents the displacement response of power law constitutive model obtained by Runge-Kutta method in the numerical analysis software Matlab. It can be seen from Fig. 11 that the displacement history curves match very well. The power law constitutive model is simulated precisely in ANSYS with the original Combin37 element.

To examine the computational efficiency of the two models, we performed the seismic response analysis example from Section 4.2 on the same computer. The power law constitutive model case took 308 s, while the Wouterse constitutive model case took 320 s. This suggests that the power law constitutive model demonstrates slightly better computational efficiency than the Wouterse constitutive model.

As a result, the nonlinear damping behavior of ECD is characterized easily by the power law constitutive model in FEA software. The power law constitutive model of ECD is a good choice for achieving an accurate and efficient analysis when considering vibration control FEA problems with ECD in this stage.

The energy dissipation capacity under harmonic motion is usually considered the key indicator of the vibration control performance of dampers. The energy consumption formula of the ECD during a cycle of harmonic motion was derived based on the power law constitutive model.

The ECD is assumed to be subjected to harmonic motion u=u0sin⁡(ωt). For ECD governed by the power law constitutive model, the energy dissipated by the ECD during a cycle of harmonic motion can be expressed as

(11)EECD=0.393Fmaxu05ω4vcr4−0.287Fmaxu04ω3vcr3−3.491Fmaxu03ω2vcr2+7.059Fmaxu02ωvcr

The detailed formula derivation is shown in Appendix A. It can be seen that EECD is a function of Fmax and vcr, when u0 and ω are specified.

The accuracy validation of Eq. (11) is conducted by comparing it with the energy consumption formula based on Wouterse constitutive model. For ECD governed by Wouterse constitutive model, the energy dissipated by the ECD during a cycle of harmonic motion can be expressed as [24]

(12)EECDW=4∫0u02Fmaxvvcr+vcrvdu=4vcrFmaxπω(1−vcrvcr2+u02ω2)

It should be noted that the maximum velocity of the harmonic motion u=u0sin⁡(wt) is u0ω. Here we take the dimensionless velocity X=u0ω/vcr, and substitute it into Eqs. (11) and (12). The EECD and EECDW can be written as

(13)EECD/Fmaxu0=(0.393X4−0.287X3−3.491X2+7.059X)and

(14)EECDW/Fmaxu0=4πX(1−11+X2)

Through observing the mathematical structure of Eqs. (13) and (14), the accuracy validation can be conducted by comparing the term (0.393X4−0.287X3−3.491X2+7.059X) in Eq. (13) with the term 4π/X(1−1/1+X2) in Eq. (14). The dimensionless energy curves EECD/Fmaxu0 and EECDW/Fmaxu0 are plotted in Fig. 12. Apparently, the power law curve fits well with the Wouterse constitutive model curve which indicates that the energy consumption formula Eq. (10) can be used to assess the energy dissipation capacity of ECD.

The equivalent linearization method is a very common damper parameters optimization method. In this section, the ECD parameter optimization is conducted based on the equivalent linearization method. The energy dissipated by the linear viscous damper is employed as a reference.

The energy dissipated by the linear viscous damper during a cycle of harmonic motion can be expressed as

(15)EL=CLπu02ωwhere CL is the linear viscous damping coefficient.

Considering the ECD is subjected to the same cycle of harmonic motion, there is no harm in defining a proportional factor μ, and the parameters Fmax in Eq. (11) can be taken as μCLu0ω. Divide EECD by EL, and it becomes

(16)EECDEL=FmaxCLπu02ω(0.393u05ω4vcr4−0.287u04ω3vcr3−3.491u03ω2vcr2+7.059u02ωvcr)=μπ(0.393X4−0.287X3−3.491X2+7.059X)where X is the dimensionless velocity which equals to u0ω/vcr.

Apparently, the term 0.393X4−0.287X3−3.491X2+7.059X is determined by the dimensionless velocity X. When the proportional factor μ, namely the parameter Fmax, is specified, we can use the dimensionless velocity X as the dependent variable to find an optimal design of ECD such that the energy dissipation of ECD is maximized as compared to that of the linear viscous damper.

Denote Y=0.393X4−0.287X3−3.491X2+7.059X and take its derivatives. It can be seen that when the parameter Fmax is specified, the energy dissipation ratio EECD/EL will reach its maximum when the dimensionless velocity equals 1.286 (See Appendix B). As a result, when the ratio of the maximum velocity of the harmonic motion to the parameter vcr is 1.286, the energy dissipation capacity of ECD reaches its maximum. It is noteworthy that the energy dissipation is also dependent on the parameter Fmax.

In this way, the optimization of the parameter critical velocity vcr of ECD is achieved based on the conclusion obtained analytically based on the power law constitutive model. The ECD parameter design will be conducted more efficiently.