Abstract
Anti-seismic devices are employed to implement the best performance of the structures under earthquakes. In this paper, semi-active tuned mass dampers (SA-TMDs) are studied by considering several combinations of variable friction forces and external disturbances. The variable damping model is used, where the goal consists in estimating the external actions to find the best friction force for system dampening. In particular, general, sinusoidal, and Gaussian dynamic loadings are considered. To obtain the response of the structure and dampers, several numerical solutions have been implemented. Probabilistic and determines analyses have been also developed to study different damper characteristics. Results show that a SA-TMD can reduce the structure displacements up to ~ 70.0% indicating a good performance in controlling different oscillations. This technology not only preserves the integrity of a structure mitigating its vibrations but also improves the life of occupants and their safety and comfort. This is beneficial from the perspective of practical application, and it is an advancement with respect to this theme.
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Introduction
Background
Technologies for the seismic protection of constructions and preventing “motion sickness” (Bekdaş et al. 2018) of residents are successfully employed in civil structures, and they have been studied in the recent years having undergone great development (Zacchei and Brasil 2022). These technologies are mainly divided into passive, active, semi-active control, and seismic isolators (Ciampi et al. 2009).
Passive controls are simple and efficient vibration absorbers. They act passively since they create reactive forces solely in response to the motion of the structure and they are not externally driven (OPCM 2005; SPES 2017). Their main problem is that they may not be suitable when the system is excited by a non-design earthquake (Chung et al. 2011; Lai et al. 2016). For instance, an extreme earthquake, difficult to prevent, with a long-period waveform may induce unexpected displacements (Zacchel et al 2017; Zacchei et al. 2018; Maddaloni et al. 2017; Chung et al. 2011).
The active controls have a great reduction of the structure response at the expense of large power consumption. They act as generating forces in the time domain; however, they may be instable and need an energy source, sensors, servo-valves, time controllers, and computers to define these forces (Jiang 2018).
Seismic isolations reduce the energy transmitted from the external loads to the structure (Bagheri and Rahmani-Dabbagh 2018; Lazarek et al. 2018) by, e.g. (i) increasing the structural period to decrease the spectral accelerations on the structures (CEN 2004, 2008); (ii) reducing inertial external forces by reducing the participating mass; and (iii) increasing the damping ratio (Ciampi et al. 2009). Reducing the mass can also avoid twisting effects, e.g. in planimetric/altimetric asymmetric structures and historical buildings (Castellano et al. 2001).
Isolators, passive, and active devices are applied for bridges, buildings, and historical structures as shown in Castellano and Infanti (2009), Shi et al. (2018b), and Lai et al. (2016). In general, passive controls and isolators are the most used.
For instance, in the Rion-Antirion Bridge in Greece, fluid viscous dampers have been applied. In Venezuela, the Caracas-Tuy Medio Railway line has more than 1500.0 steel hysteretic dampers isolators. In Algeria and in Italy, there are more than 2300.0 high-damping elastomeric isolators (Castellano and Infanti 2009). Regarding buildings, two examples in Italy are the Hospital Del Mare with 327.0 elastomeric isolators installed between piles and super-structure and the Cappuccini School with several dissipative bracing. Interesting cases, where a tuned mass damper (TMD) has been applied to reduce the oscillations, are the Taipei 101 Skyscraper in Taiwan (Castellano and Infanti 2009) and the CN tower in Toronto, Canada (Chang et al. 2018; Lai et al. 2016). Finally, for historical structures, in S. Francesco Basilica, Assisi in Italy, metal devices have been applied. In the USA, rubber isolators were first used in the Salt Lack City and County Building (Castellano et al. 2001).
Also, these technologies can be used in other fields, for instance, (i) in industrial engineering, for storage tanks (Ciampi et al. 2009), offshore platform for wind turbines (Sun and Jahangiri 2018; Jiang 2018; Hussan et al. 2018), or offshore drilling structures for oil and gas extraction (Wu et al. 2018; Sanchez et al. 2017); and (ii) in mechanical engineering, for vehicles (Trikande et al. 2017). Different aspects have been studied by researchers, such as the dynamic soil-structure interactions (Salvi et al. 2018; Jabary and Madabhushi 2018), interactions and collision with adjacent constructions (Basili et al. 2013), and multiple TMDs effects (Wen et al. 2018; Kim and Lee 2019, 2018).
In Wen et al. (2018), it was proposed the effectiveness of an innovative multiple tuned mass damper (MTMD) mitigation strategy for potential transformer by using analytical and computational finite element methods.
In this paper, the semi-active tuned mass dampers (SA-TMDs) are studied since they offer the reliability of passive devices and maintain the versatility of active devices. They are based on mechanisms like the passive controls providing a passive force but considering the mechanical characteristics in the time domain. SA-TMDs use the advantages of a controlled force without the drawback of active systems (i.e. without large energies) (Fitzgerald et al. 2018). They are small and low-cost; therefore, they have little interferences to the structure.
However, like active control, they need sensors and computers to receive the sensors’ signals and control the actuators and forces (Wang et al. 2021).
SA-TMDs are applied to control the vibration of flexible and low-damping structures under different excitations such as vehicle vibrations, wind, and earthquakes as shown in Chung et al. (2013). Several studies are available in the literature on SA-TMDs, which are divided with respect to different mechanical systems, e.g. with variable friction (Chung et al. 2011; Gaul and Becker 2014; Shi et al. 2018a; Pinkaew and Fujino 2001), variable stiffness (Nagarajaiah and Sonmez 2007; Nagarajaiah and Varadarajan 2005; Eason et al. 2013), magnetorheological (MR) dampers (Oliveira et al. 2015; Gu et al. 2017a, 2017b; Xia et al. 2016; Bahar et al. 2010; Aggumus and Cetin 2018; Zapateiro et al. 2009), and energy transition controls (Shuliang et al. 2011).
Other studies show other types of SA-TMDs, for example by using bearing made of super low-cost recycled elastomers and reinforced with fibre sheets (Maddaloni et al. 2017) and sloped rolling-type isolation devices (Chen and Wang 2017). Applications for steel structures also have been studied (Lorenz et al. 2006; Gaul et al. 2004).
In Chung et al. (2013), the numerical validation of the SA-TMD has been carried out by using several types of loadings, e.g. sinusoids with different frequencies, and random loadings.
Finally, in Elias and Matsagar (2018), Jabary and Madabhushi (2018), and Wang et al. (2018b), it was studied how the mobility and the different positioning of the damper affect the structure response. In Wang et al. (2018a) and Van Til et al. (2019), the effect of the presence of vertical barriers has been treated; in fact, when a SA-TMD exceeds the gap between its initial position and the barrier, the damper impacts on the barrier providing supplementary energy dissipation.
Motivation of this study
As mentioned, in this paper, the SA-TMD has been studied to.
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1.
Implement new standard methodologies to guarantee high-grade products and support structural engineers in acquiring the knowledge to select the most effective solution. As stated in Medeot (2017), European code [19] “represents the most complete and up-to-date document” on anti-seismic devices (see Table 6 in Annex A); however, SA-TMDs are not mentioned.
Figure 1 shows the possible types of controls (Lu et al. 2018a, 2018b). A hybrid control can combine passive with semi-active systems (Bahar et al. 2010). However, this distinction is not well defined since in Lai et al. (2016), active TMDs are called “hybrid mass dampers”, and in Medeot (2017), all the pre-existing devices combined one with each other are called “hybrids”. Table 6 (Annex A) lists the most used anti-seismic devices (i.e. passive control and isolators).
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2.
Improve its limited use with respect to other devices since it provides modern and high-tech approaches. In fact, in Wang et al. (2021), it is stated that SA-TMDs “can identify the structural instantaneous vibrational frequency and retune itself in real time”. As discussed in Maddaloni et al. (2017) and Van Til et al. (2019), these applications need more studies to improve the performances and sustainability of the structures.
The key problem of an SA-TMD is the definition of the control force, which is difficult to be estimated a priori. For this, in this paper, different multi-harmonics to simulate the external dynamic actions are adopted (this approach has been also adopted in Ma et al. (2019) and Zacchei and Brasil (2022) to simulate the seismic source). Then, numerical analyses have been implemented to find optimal solutions in terms of structural displacements. Their reduction helps improving the life of occupants and “leads to preserving the integrity of the structure” as mentioned in Zapateiro et al. (2009).
Semi-active tuned mass damper (SA-TMD) model
The SA-TMD model is formed by a structure, called “primary structure”, fixed on the base and a mass “damper” (or “secondary structure”). Both structure and mass damper have a single-degree-of-freedom (SDOF).
Figure 2 shows this configuration where the structure is placed below the mass damper, which can move between a certain limit imposed by two vertical barriers (i.e. end stop mechanism (Wang et al. 2018a; Til et al. 2019)). Barriers should reduce the SA-TMD motions, the installation space thus its costs (Til et al. 2019).
The equation of motion, in the time t, of the system is (Chung et al. 2013)
where \({\mathbb{M}}\in {\mathrm{R}}^{\mathrm{n}\times \mathrm{n}}\), \({\mathbb{C}}\in {\mathrm{R}}^{\mathrm{n}\times \mathrm{n}}\), and \({\mathbb{K}}\in {\mathrm{R}}^{\mathrm{n}\times \mathrm{n}}\) are the inertia, damping, and stiffness matrices, defined, respectively, as
where the three coefficients mi > 0, ci > 0, and ki > 0 are the masses, damping, and elastic stiffness coefficients, respectively. The subscripts s and d refer to the structures and mass damper, respectively.
The function of kd is to distribute the energy from the primary to the secondary structure, whereas cd dissipates this energy; for this, the secondary structure can be considered as a damper.
The components of \(x(t)={\left[{x}_{d}\left(t\right), {x}_{s}(t)\right]}^{\mathrm{T}}\in {\mathrm{R}}^{\mathrm{n}}\) represents the displacements, where the variables \(\dot{x}(t)\) and \(\ddot{x}(t)\) are the first and second time derivate of x, respectively. Matrices \({\mathbb{b}}={\left[1,-1\right]}^{\mathrm{T}}\in {\mathrm{R}}^{\mathrm{n}}\) is the variable friction force location vector, and \({\mathbb{e}}={\left[0, 1\right]}^{\mathrm{T}}\in {\mathrm{R}}^{\mathrm{n}}\) is the external disturbance location vector. Finally, u(t) is a variable friction force, and w(t) is the external disturbance. The system is forced kinematically by springs ki and w(t).
Equation (1) in a first-order state-space form can be expressed as
where \(z(t)={\left[x\left(t\right), \dot{x}(t)\right]}^{\mathrm{T}}\in {\mathrm{R}}^{\mathrm{n}}\) is the state vector, \({\mathbb{B}}={\left[0,{\mathbb{M}}^{-1}{\mathbb{b}}\right]}^{\mathrm{T}}\in {\mathrm{R}}^{\mathrm{n}}\) is the state-space variable friction force location vector, \({\mathbb{E}}={\left[0,{\mathbb{M}}^{-1}{\mathbb{e}}\right]}^{\mathrm{T}}\in {\mathrm{R}}^{\mathrm{n}}\) is the state-space external disturbance location vector, and the system matrix \({\mathbb{A}}\in {\mathrm{R}}^{\mathrm{n}}\) is
In other words, \({\mathbb{A}}\in {\mathrm{R}}^{\mathrm{n}\times \mathrm{n}}\) denotes the system matrix composed of the mass, damping, and stiffness matrices, whereas \({\mathbb{B}}\) and \({\mathbb{E}}\) represent the distribution matrices of the control forces and the excitations, respectively.
The exact solution of Eq. (5) is
where c1 is an arbitrary constant of integration.
Equation (5) provides some solutions including sums and integrals that are difficult to be carried out directly. Therefore, some variables substituted by t are used. In this sense, Eq. (7) can be also developed in the discrete-time state-space form (Lu et al. 2004; Lai et al. 2016).
Under the non-state-space form (i.e. z(t) → non-state vector and A = B = E = 1), for initial condition z(0) = 0 and u(t) = w(t) = {cos(t), sin (t)}, it is possible to plot Eq. (7) trend as shown in Fig. 3.
An ideal control of this model could be indirectly achieved by adjusting mechanical parameters such as stiffness and/or damping. For this, SA-TMDs can be divided into two sub-models: (i) damping model (i.e. u(t) ≠ 0, used in this work) and (ii) stiffness model (i.e. u(t) = 0, k(t) ≠ 0). The former is treated in the “Variable damping model” section, whereas the latter basically consists in using, for instance, a time varying stiffness of the device as (Nagarajaiah and Varadarajan 2005; Chandiramani 2016):
where ke is spring’s constant stiffness, and θ(t) is the time-varying angle between ke and the axis of the device direction, which reaches a maximum value for θ(t) = 0 and a minimum value for θ(t) = π/2 (for more details, see (Nagarajaiah and Varadarajan 2005; Chandiramani 2016)). k(t) is included in the stiffness matrices \({\mathbb{K}}\) in Eq. (1) representing the internal forces of the system (Nagarajaiah and Sonmez 2007). As shown in Eason et al. (2013), in real applications, the stiffness tuning is achieved by a feedback control system, which monitors the structural response, calculates the dominant frequency of the excitation, and thus adjusts the stiffness.
Finally, Eq. (1) can be also represented in terms of energies (Medeot 2017). In this sense, it is possible to define the performance of the dynamic system by calculating the energy dissipated from devices and the energy input from external disturbances. Thus, the performance is the portion of the energy input that the system can dissipate.
Considering Eq. (1), the relative energy balance of the system between internal and external energies is defined as (Basili et al. 2013)
where Ek(t) is the kinetic energy, Ed(t) is the energy dissipated by dampers, Ee(t) is the elastic energy, Eu(t) is the energy of variable friction forces, and Ew(t) is the energy of external disturbances.
Variable damping model
The goal of this variable damping model is that the friction force to be like the desired control force. This model is an alternative strategy for dissipation the external excitations under specific configurations (Chung et al. 2011; Shi et al. 2018a; Lu et al. 2004).
Figure 4 shows a possible configuration of a friction system introduced in Shih and Sung (2021a, b). The main components are the bevel casting tube, switching tube, and locking steel ball linked with a cover plate by an internal spring. The internal mechanisms of this device are not treated in this study; here, only the output u(t) form is studied. Basically, the general mechanism is divided into three phases: (i) registration of the external actions w(t); (ii) processing of w(t) by SA-TMD; and (iii) releasing of the u(t) output on the structure to reduce its response (for more details, see (Shih and Sung 2021b)).
The force balance of the α/2 angle in the horizontal directions is
where the friction force u(t), which is controlled indirectly by the normal friction force N(t), is defined by Coulomb’s model as (Chung et al. 2011)
where μ is the friction coefficient of the force defined as tan(α/2), and |·| is the absolute value. sgn(·) indicates that the control force produced by a variable damper is opposite to the direction of the current damper motion (i.e. passive resistance) (Lu et al. 2004). u(t) in Eq. (11) is placed in the right-hand side of Eq. (1); therefore, it represents an external force.
As already mentioned, the definition of u(t) is the problem key, which is difficult to be estimates a priori since w(t) is unknown. For this, several cases have been generated as explained in the “Input motions” section.
Input motions
Three types of non-stationary loadings are considered: general, sinusoidal, and Gaussian dynamic loading. A general dynamic loading simulates irregular and aleatory time-histories (THs), which can be used to represent, e.g. earthquakes, wind, machines’ vibrations, and aerodynamic loads (Luzi et al. 2020). A sinusoidal harmonic loading can be used to simulate a more regular trend, e.g. temperature, humidity, long waves, sloshing, and convective pressures (Chung et al. 2013). Finally, Gaussian loadings could represent, e.g. impulsive actions, concentrated forces, and jumping excitations.
By considering these three loads, Eq. (1) becomes
where Au and Aw are the amplitude of the force u(t) and w(t), respectively, ωi is the circular frequency, ϕi is the random phase between 0 and 2π, and N is the arbitrary number of harmonic components.
Materials and methods
Materials
The used data regard deterministic and random values. Some pseudo-random parameters correspond to the damper data, whereas the structure data are imposed. The key values for the analysis are the mass, period, and damping ratio of the structure and the mass damper. The goal is to obtain a ratio μr ≈ fr ≈ 1.0% (Eq. (13)) as suggested in Chung et al. (2013) and Jabary and Madabhushi (2018), which provides the optimum damper response as suggested in Chung et al. (2013).
To define several values of Td near to Ts, the stochastic Monte Carlo simulation (MCS) is performed. It generates pseudo random variables (RVs) within a predefined range where each parameter follows an adopted probability density function (PDF) (Su and Xu 2014; Hu et al. 2016). MCS consists in choosing an RV with a probability distribution in the range RVmin to RVmax up to a list of random values Ns. Here, the used range is − 0.50 ≤ RV ≤ 0.50 with Ns = 1.0 × 106 (Zacchei and Nogueira 2021).
Figure 5 shows MCS points (Fig. 5a) for Td and the normal PDFs for the three dampers (Fig. 5b).
Table 1 and Fig. 6 show the adopted data of the structure and dampers.
Two dimensional mass, μr, and frequency, fr, ratio are introduced to standardise the structure-damper system (Elias and Matsagar 2018; Salvi et al. 2018):
where fd is the mass damper frequency (= 1/Td) and Ωs,j = Ωs,1,…,Ωs,n (= 1/Ts,1, …, 1/Ts,n) is the selected modal frequency of the structure corresponding to the mode j. A possible criterium to distribute the damper masses on the structure is carrying out the modal analysis (Elias and Matsagar 2018; Wu et al. 2011).
The structural values in Table 1 refer to the first mode of vibration since the control of the only lower modes is usually enough to mitigate the vibrations. The used values should represent in a realistic way the system in accordance with the literature (Chung et al. 2011; Eason et al. 2013; Kim and Lee 2019; Lu et al. 2018b) and design recommendations (Kim and Lee 2018). In general, for civil structures, it is usually assumed μr < 10.0% (Jabary and Madabhushi 2018) and ξd > ξs (CEN 2004, 2008; Shi et al. 2018a). However, ξs might not considered adequately some complex parameters as the material heterogeneity and the influence of the structural and non-structural elements (Zacchei et al. 2020), whereas ξd can be estimated more easily since dampers are construct in laboratory, their sizes are small, and the material is homogeneous.
Figure 7 shows the schematic configuration of this study: three types of dampers with different period ratios are adopted to evaluate the damping effectiveness on the structure. Table 2 lists the characteristics of these dampers where Td is generated by MCS, which provide semi-probabilistic parameters, i.e. kd and cd (Elias and Matsagar 2018).
Finally, regarding the input motions (Eq. (12)), the following values are adopted: Au = 10.0 N, Aw = 100.0 N, and N = 100.0. Each simulation was set up such that the structure undergoes ~ 400.0 cycles of oscillation.
Methodology
Numerical solutions
Numerical simulations have been carried out to obtain the design parameters for the structure and dampers. By expanding Eq. (5), we obtain
Considering the second line of Eq. (14), which represents the accelerations \(\ddot{x}(t)\), we obtain
of which two partial differential equations (PDEs) with respect to \({\ddot{x}}_{s}(t)\) and \({\ddot{x}}_{d}(t)\) are obtained (Shi et al. 2018a):
In this study, Eqs. (16) and (17) are developed using Hermite polynomials (HPs) (Dattoli et al. 1998) by Mathematica software (Wolfram Mathematica 2017). An HP with the non-negative degree n in time t (t ∈ R) is specified by the series (Dattoli 2000):
As known, Eq. (18) provides the exact solution of a second-order homogeneous PDE (in the classical form) as shown in Yari and Mirnia (2021) and Abramowitz and Stegun (1965). However, Eqs. (16) and (17) present some differences with respect to the classical form (e.g. they are not homogeneous); therefore, it is necessary to define determined initial conditions (i.c.) to avoid arbitrary constants during the numerical integrations. Thus, the structure and damper displacements with the i.c. are described by
The process consists in finding the numerical solutions to a set of PDEs with several unknown functions xj that depend on one or more independent variables tj. Numerical PDEs represent solutions for the functions xj by “interpolating function” (IF), which is the HP interpolation defined as a generalisation of linear interpolation (Eq. (18)). The IF provides approximations to the xj over the range of values tinitial to tfinal for the independent variables tj. The process starts with a value of tj, and then it takes a sequence of steps, trying to cover the whole range tinitial to tfinal (Mathematica 2017).
Optimization process
The goal of the optimization process consists in minimising the displacements, velocities, and accelerations of the primary structure and SA-TMDs under different types of excitations. There are different optimization strategies and objective functions as shown in Nagarajaiah and Varadarajan (2005), Elias and Matsagar (2018), and Salvi et al. (2018). Here, the following problem is used, with the parameters defined in a domain Ω (e.g., ΩT refers to the parameter T) (Salvi et al. 2018):
where J(pi) is set as the objective function of the variables pi; bL and bU are the lower and upper bound of the optimization variables, respectively.
Since several combinations have been carried out, it is useful to consider a root mean square (RMS) defined for n values by
Figure 8 shows the flowchart of the general methodology highlighting the main 5 + 2 steps from the start (step 0) to the end (step 6). They consist in (1) description of the mathematical model (Eq. (1)); (2) transformation of the model in a state-space form (Eq. (5)); (3) definition of the input data by deterministic and probabilistic approaches; (4) developing numerical solutions; (5) choice of the optimization criteria and plotting of the results. If the results non are satisfactory, it is possible to adjust the i.c., bL, bU, and/or other parameters.
Analyses and results
Structure and dampers response
From Eqs. (16) and (17), the response in terms of displacements, velocities, and accelerations for the structure and damper during a motion of 30.0 s (i.e. t > 25.0 s as suggested in OPCM (2005)) has been obtained. The goal is to equilibrate the external disturbance w(t) with respect u(t).
Figures 9, 10, and 11 show the TH of the structure (blue curve) and the three dampers (black curve) with Td = 5.99 s when u(t) = w(t), and with Td = 6.20 s, Td = 5.71 s when u(t) ≠ w(t). The dashed black lines in the displacement trends represent the blocked threshold assumed of 5.0 cm of the barriers (Fig. 2).
In the acceleration diagrams in Figs. 10 and 11, it is possible to identify better that the damper response follows the adopted u(t), whereas the structure response follows w(t) trend since it acts directly, and with high amplitudes, to the mass ms as shown in Eq. (16).
Figures 9, 10, and 11 clearly show the reduction of the structure response associated with the SA-TMD configuration. In general, xd is higher than xs, as indicated in Chung et al. (2013), since, physically, the damper receives the external loading w(t) and transmits it to the structure with a lower amplitude.
In Fig. 9 where the same external loadings are adopted (i.e. u(t) = w(t)), it is possible to note some general considerations. Sinusoidal and general loads increase the response of the structure and dampers in t, whereas the Gaussian load tends to reduce these responses indicating a better solution. If the peak values are observed at the beginning (e.g. Gauss-Gauss loading), the damping performance in terms of RMS is strongly influenced by these peaks.
However, the good performance on the system under the Gaussian load (Figs. 10 and 11) could be not verified for large period; in fact, from t > 20.0 s, the displacements of the damper increase reaching a high value at t ≈ 30.0 s like the initial amplitude.
In Fig. 9, for the sinusoidal loads with a w(t) frequency of 0.159 Hz, it is possible to see the resonance phenomenon between w(t) and the system; in fact, the maximum displacements (i.e. xd ≈ 0.90 m and xs ≈ 0.10 m) are verified for this case for fd = 0.166 Hz ≈ 0.159 Hz.
Comparisons and discussions
Figure 12 shows some resumed results where it is possible to see that the damper 3 more reduces the structural response with respect the damper 1 (Fig. 12a). For this, in Fig. 12b, the best results are plotted showing the minimum values of xs ≈ 1.0 cm and xs ≈ 0.38 cm for the gen-Gauss and gen-gen combination, respectively.
It is important to note that, by using the same function for u(t) and w(t) loads, the best equilibrium should be expected since the external disturbance w(t) is compensated, in terms of energy, by the variable friction force u(t) (Eq. (9)). However, the use of a general random load for u(t) to equilibrate w(t) could be hazardous since it is intrinsically difficult to control this type of load. For this reason, the gen-Gauss combination is considered the best combination in this study. Also, the gen-Gauss combination provides smaller relative displacements (i.e. xs(t) – xd(t)) than those obtained for gen-gen combination (see Fig. 13a). This is a positive effect since minimising the relative displacements the integrity of the structure is preserved (Zapateiro et al. 2009).
Figure 13 shows the values of xs in relation to xd; in particular, Fig. 13a shows their relative displacements (xs(t) – xd(t)), whereas Fig. 13b shows their values by loop displacements.
The phase between the curves in Fig. 13a is because w(t) ≠ u(t) with different periods. This phase tends to increase for gen-gen combination, whereas for gen-Gauss tends to decrease. In general, when xs – xd > 0 (i.e. xs > xd), the structure is subjected to an increasing of displacements (i.e. xs ↑), which could be critical if it is not damped; otherwise, when xs – xd < 0, xd tends to increase (i.e. xd ↓); however, it is also controlled by barriers.
In Fig. 13b, it is possible to see that for gen-gen combination, the damper 1 (solid black curve) follows a trend more linear (i.e. curves more elongated and inclined) with respect the damper 3 where the trends are more circular. This indicates that the maximum xd values are reached for extreme xs values. Contrary, for the gen-Gauss combination, damper 1 reaches the maximum xd value at xs ≈ 0 (dashed black curve).
Also, for the gen-Gauss combination, both dampers follow a similar trend probably because a Gaussian load for u(t) provides a more stable response. Both dampers provide quasi-overlapping curves due to a similar randomness of w(t) in terms of energy.
Figure 14 shows the displacements of the structure and damper 3 and their PDF (Kim and Lee 2019). The amplitude of the PDF for the damper 3 is higher than the PDF for the structure. This means that the structure has a minor variation between the negative and positive displacement peaks, i.e. the curve is sharper when the displacement oscillations are smaller indicating a good control.
Tables 3 and 4 summarise the results in terms of displacements and accelerations for different simulations. Grades from 1 to 3 are assigned to quantify the goodness of the results: (i) for the structure, xs < 1.0 cm (good), 1.0 ≤ xs ≤ 4.0 (fair), and xs > 4.0 cm (poor); (ii) for the dampers, xd > 5.0 cm one time (good), two times (fair), more times (poor). These limits were defined with respect to the adopted barriers threshold of 5.0 cm and previous studies (Table 5).
The results have been compared to the literature as shown in Table 5 and Fig. 15. It is difficult to homogenate the values found in other studies since each structure, even if similar, has its own behaviour. In fact, as mentioned in Ghorbanzadeh et al. (2021), the efficiency of an SA-TMD “depends entirely on the dynamic characteristics of the structure”. In this sense, here the criterium of homogenisation regard the absolute response of the non-damped structure, xs*, with respect the damped structure, xs.
From previous studies where an SA-TMD is applied on a structure, possible efficient values between 0.25 and 0.50 are consistent with this study, i.e. 0.395 ≈ 0.318. In Chung et al. (2011), a high ratio of 0.602 has been estimated since it refers to the response of the SA-TMD with respect to a passive TMD, which corresponds to the contribution of \({\mathbb{C}}\dot{x}\left(t\right)\) in Eq. (1). Actually, by comparing two dampers, the ratio would tend to be 1.0.
Finally, some critical aspects should be mentioned, e.g. for large external excitations, these combinations could not work well. The variation of the structure stiffness should be considered since they can reduce damper efficiency. The used mathematical model does not consider the influences of the high frequencies, modal combinations, non-linear analyses, and soil-structures interactions. Also, it is necessary to consider the site conditions and earthquake characteristics to design well SA-TMDs. These aspects could be future challenges for the authors (Zacchei et al. 2020; Zacchei and Brasil 2022; Zacchei and Lyra 2022).
Conclusions
In this paper, SA-TMDs on a structure under a variable damping model are investigated. The main conclusions are as follows:
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1)
Numerical analyses have been carried out to simulate several multi-harmonic excitations for external, w(t), and controlled damper, u(t), forces. This approach should capture the seismic input, which is unknown a priori. The goal is to calibrate u(t) in function of w(t). Deterministic and probabilistic data have been adopted to consider different characteristics for dampers (3 dampers on 1 structure) thus their behaviour. The used fd ranges between 0.159 and 0.175 Hz.
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2)
In general, xd > xs since the damper receives the external loading w(t) and transmits it to the structure with a lower amplitude. Results in Figs. 9, 10, and 11 show that sinusoidal and general loadings increase the response of the structure and dampers in t, whereas the Gaussian loadings tend to reduce these responses. However, the good performance on the system under the Gaussian load could be not verified for large period. Under resonance effects, it is possible to reach values of xd ≈ 0.90 m and xs ≈ 0.10 m.
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3)
The best results are obtained for gen-Gauss and gen-gen combinations with minimum values of xs ≈ 1.0 cm and xs ≈ 0.38 cm, respectively. Given that the general random load for u(t) to equilibrate w(t) could be difficult to be controlled, the gen-Gauss combination appears the best combination in this study. Also, considering relative displacements (xs(t) – xd(t)), for this combination, the phase tends to decrease, and it provides a more stable response. An optimum SA-TMD can reduce the structure displacements up to ~ 70.0% indicating a good performance in controlling different oscillations.
Finally, the effectiveness of the studied SA-TMD mitigation strategy is very sensitive to the random nature of loadings, which should represent the expected earthquake frequency contents. For this, we hope in the future to carry out experimental campaigns to improve the studied model with other effects such as the influences of the high frequencies, stiffness variations, and real seismic inputs.
Data availability
Data will be made available on request.
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Acknowledgements
The first author acknowledges the Itecons Institute, Coimbra, Portugal, for the Wolfram Mathematica license and the University of Coimbra (UC), Portugal, to pay the rights (when applicable) to completely download all papers in the references. The second author acknowledges support by CNPq and FAPESP, both Brazilian research funding agencies.
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Annex A
Annex A
There is a wide range of anti-seismic devices, which can be divided conceptually in:
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1.
Isolation a structure with respect to the external forces (e.g. increasing the period or reducing the forces).
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2.
Damping the energy by adjusting the velocities (e.g. dissipation of controlling velocities).
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3.
Damping the energy by adjusting the displacements (e.g. dissipation of relative displacements).
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4.
Stiffening the structure with rigid connections (e.g. changing the behaviour of the structure).
Table 6 lists the classification, description, and some useful values for each anti-seismic device. The first, second, and third devices must support at least 10.0 complete loops. Moreover, their mechanical characteristics, in the loops following the first one, will not vary by more than 15.0% compared to the characteristics during the third loop (OPCM 2005). A general design rule in terms of energy is that the reversibility of stored energy is ≥ 0.25 of the energy dissipated (Medeot 2017).
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Zacchei, E., Brasil, R. Semi-active tuned mass dampers under combined variable actions of friction forces and external disturbances. Arab J Geosci 16, 458 (2023). https://doi.org/10.1007/s12517-023-11567-y
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DOI: https://doi.org/10.1007/s12517-023-11567-y