Optimization of VEDs for Vibration Control of Transmission Line Tower

Huang, Guoping; Hu, Jianhua; He, Yuzhu; Liu, Haibo; Sun, Xiugui

doi:https://doi.org/10.1155/2021/9060414

Advances in Civil Engineering

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Volume 2021 | Article ID 9060414 | https://doi.org/10.1155/2021/9060414

Optimization of VEDs for Vibration Control of Transmission Line Tower

Guoping Huang,^1,2Jianhua Hu ,³Yuzhu He,²Haibo Liu,³and Xiugui Sun⁴

Academic Editor: Nan Zhang

Received30 Aug 2021

Accepted07 Oct 2021

Published19 Oct 2021

Abstract

This paper investigates the optimization of viscoelastic dampers (VEDs) for vibration control of a transmission line tower. Considering the stiffness of the steel brace connected to a VED, the mechanical model of the VED-brace system was established. Subsequently, the additional modal damping ratio of the transmission line tower attached with VEDs was obtained analytically. Furthermore, the finite element model of a two-circuit transmission line tower with VEDs was built in ANSYS software, and the influences of installation positions and parameters of VEDs on the additional modal damping ratio were clarified. In addition, the control performance of VEDs on the transmission line tower subjected to wind excitations was emphatically illustrated. The results show that the stiffness of the steel brace connected to a VED has a significant effect on the maximum additional modal damping ratio of the VED-brace system provided for the transmission line tower and the optimal parameters of the VED. Meanwhile, the installation positions of VEDs dramatically influence the additional modal damping ratio. Moreover, the increase of the brace stiffness and the loss factor is beneficial to improve the control performance of VEDs. Besides that, the VEDs present superior control performance on the top displacement of the transmission line tower as well as the transverse bending vibration energy.

1. Introduction

Transmission line tower is one of the typical high-rise structures, which is widely used throughout the world for energy supplying [1, 2]. The transmission line tower is vulnerable to suffering from wind-induced vibrations owing to its high flexibility and low inherent damping characteristics [3–5]. Frequent and excessive vibration could potentially induce damage and even collapse of the transmission line tower and have adverse effects on the serviceability of the whole transmission tower-line system [6–8]. Considerable investigations focused on theoretical [9–11], experimental [12–14], and field measurement [15] have been carried out in recent decades, which is devoted to mitigating the dynamic responses of the line transmission tower. To guarantee the normal operation of the transmission line tower, several measures have been proposed for the vibration control of the transmission line tower, which mainly include increasing the stiffness of the transmission line tower [16, 17] and attaching energy dissipation devices on the transmission line tower.

Attaching energy dissipation devices is a commonly used method for mitigating vibrations of the transmission line tower [18–20]. The tuned mass damper (TMD) is a typical energy dissipation device, which has been commonly utilized for mitigating vibrations of high-rise structures [21, 22]. It has been found that the application of TMDs helps reduce the dynamic responses of the transmission line tower [23–25]. However, the disadvantage is that several additional masses should be installed on top of a transmission tower, which requires the occupancy of the structural space. To overcome the shortcomings of the TMD, several energy-dissipating dampers were further proposed to enhance the vibration control performance of the transmission line tower. The magnetorheological (MR) damper has been successfully used on suppressing the wind-induced response of a real transmission line tower [26]. It has shown that the MR damper with optimally designed parameters has some advantages in controlling the wind-induced response of the transmission line tower. Nevertheless, the MR damper is quite complicated, and the requirement in the additional energy supply during the vibration control process is unrealistic while accepting strong excitations. Besides that, the passive friction dampers have been used in a finite element tower model with lumped mass, which is further applied in a real transmission line tower for verifying its superior control performance [27]. In addition, the use of viscoelastic dampers (VEDs) for the wind-resistant design of the transmission line tower has also been proposed [28]. Note that the optimal design of VEDs for vibration control of the transmission line tower has not been investigated.

This paper investigates the optimal design of VEDs for vibration control of a transmission line tower subjected to wind excitations. The paper is organized as follows. Firstly, the mechanical model of the VED-brace system was established. Subsequently, the maximum additional modal damping ratio of the transmission line tower attached with VEDs was calculated. Next, based on the finite element model of a two-circuit transmission line tower with VEDs, the influences of installation positions and parameters of VEDs on the additional modal damping ratio were clarified. Finally, the control performance of VEDs on the transmission line tower subjected to wind excitations was numerically demonstrated.

2. Model of VED-Brace System and Optimal Design of VED

2.1. Mechanical Model of the VED-Brace System

A coupled system combined with a viscoelastic damper and a supported steel brace, also denoted as VED-brace system, is shown in Figure 1. The VED is represented by a parallel spring (with stiffness K_d) and damper (with damping coefficient C_d), while the supported steel brace, connected to the VED and primary structure, is modeled by a spring with stiffness K_b and in series with the VED. Assuming that a sinusoidal displacement with amplitude u₀ and natural frequency ω is applied on the VED, its output force is given aswhere denotes the first-order derivative of with time t.

Introducing the energy dissipation stiffness of VED as , the output force of the VED can be rewritten as

Supposing that the displacement of the VED-brace system is represented by u_A = u_asinωt, the displacement of the VED and the brace can be expressed aswhere φ is the displacement phase difference between the VED and the brace.

Based on the equality of internal force for the series system, we obtainwhere

The ratio of the relative displacement amplitude at both ends of the VED to the relative displacement amplitude at both ends of the VED-brace system is expressed as

According to equation (7), it is straightforward to see that the ratio β approaches 1 if the brace stiffness K_b is sufficiently large. Otherwise, the effect of the limited stiffness of the steel brace must be included during vibration control analysis. For the convenience of analysis, the nondimensional parameters are introduced here:where α denotes the ratio of the brace stiffness to the damper stiffness; α₁ is the ratio of the energy storage stiffness of the VED-brace system to the energy storage stiffness of the VED; α₂ denotes the ratio of the energy dissipation stiffness of the VED-brace system to the energy storage stiffness of the VED; η denotes the loss factor of the VED, and its typical value ranges from 0.2 to 5.0.

Figure 2 shows the variations of β, α₁, and α₂ with respect to the stiffness ratio α. It can be seen from Figure 2(a) that β increases with α and will eventually converge to 1, which means that increasing the brace stiffness is beneficial to improve the energy dissipation efficiency of the VED. As shown in Figure 2(b), when α is greater than 2, α₁ will be greater than 1, and K_a finally converges to K_d as K_b continues to increase. In this case, the brace can be regarded as a rigid rod, indicating that the energy storage stiffness of the VED-brace system is equal to the energy dissipation stiffness of the VED. It can be found in Figure 2(c) that α₂ increases with α. Moreover, finally converges to as α grows, which can be considered that the energy dissipation stiffness of the VED-brace system is also equal to that of the VED.

(a)

(b)

(c)

2.2. Optimal Design of VED

The simplified model of the tower segment with the VED-brace system is depicted in Figure 3. Note that the VED-brace system is connected in parallel to the main member of the transmission line tower.

Assume the relative displacement of both the i end and j end of the tower segment as

For the tower segment coupled with the VED-brace system, the output force becomes

The equivalent damping ratio for the tower segment may be obtained as

By defining the additional stiffness ratio α_a = /K_f, equation (10) can be rewritten aswherewhere α_b = K_b/K_f represents the ratio of the brace stiffness to the tower segment stiffness; α_d = /K_f represents the energy dissipation stiffness ratio of the VED.

From equations (12a) to (12c), it is shown that α_a and ξ_a are dependent on α_b, α_d, and η. Again, η is taken as 1.4. Figure 4 shows the variations of the stiffness ratio α_a with respect to α_d under various α_b. It is apparent that the stiffness ratio α_a increases with the increase of α_d and approaches α_b for a large α_d. This is because extremely large damper stiffness will lock the damper, which causes the damper to fail to dissipate the vibration energy. The variations of the equivalent damping ratio ξ_a with respect to α_d under various α_b are further illustrated in Figure 5. Note that the equivalent damping ratio ξ_a firstly increases with the increase with α_d, reaching the maximum value when the α_d reaches a certain value, and then decreases with the increase of α_d.

By taking the derivatives of the damping ratio ξ_a with respect to α_d, there is

By defining and letting , we obtain

Substituting equations (14) into equation (12c), the peak damping ratio is derived as

The variations of the peak damping ratio ξ_a,peak with respect to the stiffness ratio α_b for η = 1.4 and loss factor η for α_b = 0.2 are illustrated in Figure 6. As shown in Figure 6, the peak damping ratio ξ_a,peak increases with the increase of stiffness ratio α_b and loss factor η. In summary, equation (15) describes peak damping ratio for the tower segment when equation (14) is fulfilled. These two equations constitute the optimal parameter design for VEDs in the transmission line tower.

After the brace stiffness K_b and the loss factor η of the VED are determined, the damping ratio of the energy dissipation system reaches the maximum value. The ratio of the equivalent energy storage stiffness K_d of the VED to the brace stiffness K_b can be calculated by the following formula as

It should be noted that when the additional modal damping ratio of the VED-brace system reteaches maximum, its energy dissipation efficiency is also the largest. Thus, the optimal parameters of the VED-brace system can be determined by equations (14) and (16), and the maximum additional modal damping ratio of the tower section can be calculated by equation (15).

3. Numerical Simulation of a Transmission Line Tower with VEDs

3.1. Finite Element Model of Transmission Line Tower

To investigate the vibration control performance of VEDs for a transmission line tower, a three-dimensional finite element model of a two-circuit transmission line tower shown in Figure 7 is built in ANSYS software. The transmission line tower height is 103.6 m, and two cross arms are symmetrically arranged at the heights of 57 m, 78.2 m, and 99.6 m above the ground. The end of the cross arm is 16.6 m, 17.6 m, and 20.22 m away from the center of the transmission tower, respectively. The main structure of the transmission line tower is composed of steel pipes and connected with high-strength bolts. The cross section of the steel pipe is varied with height of the transmission line tower. The most important stressed components are the four tower columns, and their cross-sectional area decreases from bottom to top. The main material parameters of members are as follows: elastic modulus 206 GPa, density 7850 kg/m³, and Poisson’s ratio 0.3.

(a)

(b)

(c)

The spatial beam element BEAM188 is used for each member, without considering the coupling vibration of the conductor, ground wire, and transmission tower. The transmission line tower without control consists of 527 nodes and 1406 elements in total. The overall coordinate system is divided into the horizontal X axis, the forward Y axis, and the Z axis along with the tower height. The origin of coordinates is at the midpoint of the bottom of the tower. The first three mode shapes of the transmission tower are obtained by modal analysis, as illustrated in Figure 8. The first mode shape is the bending vibration mode perpendicular to the conductor direction, the second mode shape is the bending vibration mode along the conductor direction, and the third mode shape is the torsional vibration mode rotating around the centerline of the tower. Based on the finite element model of the transmission tower, the modal analysis of the transmission tower is carried out, and the properties of the transmission line tower shown in Table 1 are further obtained.

(a)

(b)

(c)

3.2. The Installation Position of VED

Figure 9 presents the strain energy distribution in the transmission tower for the first second mode. It can be seen from Figure 9(a) that the first modal strain energy of the primary members is much greater than that of the inclined bars and the cross arms, and the first modal strain energy of the lower part of the tower legs is also greater than that of the upper parts. As shown in Figure 9(b), the distribution law of the second modal strain energy in the transmission tower is consistent with that of the first modal strain energy. Thus, the VEDs should be installed on the lower primary members with the largest possible modal strain energy, which helps to efficiently control the vibration of the transmission line tower for the first two modes.

(a)

(b)

The main tower columns with the same function are recorded as a unit, and there are 72 main tower column units numbered from bottom to top of the transmission line tower. The axial deformation of each main tower column for the first mode is shown in Table 2. The variations of the axial deformation with the unit number are further illustrated in Figure 10. Note that the large deformation occurs at the 1, 2, 3, 4, 21, 22, 23, 25, and 49 units of the transmission line tower. To effectively control the bending and the axial deformation of the transmission line tower, the installation positions of VEDs need to be taken into account in combination with the data in Table 2 and Figure 10. There are mainly two installation schemes: scheme 1 is to install VEDs on the tower column unit with large axial deformation, and scheme 2 is to install the same number VEDs with the same parameters as scheme 1 on the tower column unit from the bottom to top of the transmission line tower. 44 VEDs used in installation scheme 1 are installed in parallel on the four main tower columns of the transmission tower, and 44 VEDs used in installation scheme 2 are installed on the tower column unit from bottom to top of the transmission line tower. Note that the unit numbers of VEDs corresponding to installation scheme 1 and installation scheme 2 are shown in Table 3.

3.3. The Optimal Parameters of VED

The outer diameters of the circular steel pipes of the main tower columns of the transmission tower vary from 109.5 mm to 213 mm, and the wall thickness of the steel pipes varies from 6 mm to 10 mm. K = EA/L is the axial stiffness of the tower column unit, A is the area of steel pipe, and L is the unit length. The stiffness of the tower column unit installed with VEDs is shown in Table 4.

For the convenience of calculation and analysis, the ratio of the stiffness between each brace and each tower column is taken as 0.2, and the loss factor of the VED is taken as 1.4. Then, the ratio of the equivalent energy storage stiffness of the VED to brace stiffness λ can be calculated by equation (16), and the additional modal damping ratio ξ_a of the transmission line tower installed with VEDs can be further gained. The stiffness of the i th tower segment, the energy storage stiffness of the i VED, and the energy dissipation stiffness of the i VED are defined aswhere a_bi denotes the ratio of the brace stiffness to the tower column unit stiffness; K_fi denotes the axial stiffness of the tower column; λ_i denotes the ratio of the energy storage stiffness of the VED to the corresponding brace stiffness.

Equations (17)–(19) require that the parameters of VEDs in each tower section be different, which increases the difficulty of manufacturing dampers. Thus, the VEDs with the same parameters are used in this paper. Furthermore, the equivalent damping coefficient of the VED-brace system can be defined as

3.4. Calculation Method of Supplemental Modal Damping Ratio

There are mainly two methods used in calculating the additional modal damping ratio of the transmission line tower installed with VEDs: the modal strain energy method and the complex mode calculation method. The modal strain energy method is regarded as a simple method, which assumes that the tower frequency and vibration mode show less variation before and after installing VEDs. When the modal strain energy method is adopted, the additional modal damping ratio of the transmission line tower provided by VEDs can be expressed aswhere E_d denotes the consumed energy by all VEDs in one cycle; n_d is the number of VEDs; u_i is the elongation at both ends of the VED; E_s is the modal strain energy of the tower in one vibration cycle. It can be seen from equation (21) that the modal damping ratio can be calculated by the parameters of the VED and modal parameters such as the vibration mode and frequency of the transmission line tower.

When using the complex modal analysis method, it is necessary to establish the finite element model of the tower-VED-brace system. The VED-brace system is regarded as a mechanical model with equivalent stiffness and equivalent damping, which is simulated with COMBIN14 element in ANSYS software. A total of 44 COMBIN14 elements are attached to both ends of the main tower column units of the transmission line tower. In the establishment of the COMBIN14 element, only one COMBIN14 element is needed to be added to the transmission tower node with VEDs, and the program automatically defaults that the two elements are in parallel mode. Accordingly, it is very convenient for establishing the finite element model of the tower-VED-brace system. In addition, the modal damping ratio can be further obtained by the complex modal analysis method. And the r th vibration circular frequency and modal damping ratio of the transmission tower are computed as

3.5. Influence of Installation Position and Parameters of VEDs on the Additional Modal Damping Ratio

The brace stiffness is taken as 0.1 to 0.2 times the tower column unit stiffness, and the loss factor η of the VED is taken as 1.4. The ratio of the equivalent energy storage stiffness of the VED to brace stiffness λ is calculated as 0.531 by equation (16). Based on the modal strain energy method and the complex modal analysis method, the variations of the first additional modal damping ratio ξ₁ with α_b provided by VEDs under two installation schemes are presented in Figure 11. It can be seen from Figure 11 that the first additional model damping ratio ξ₁ of provided by VEDs installed in accordance with installation scheme 1 is greater than that provided by VEDs installed in accordance with installation scheme 2. Hence, since installation scheme 1 is superior to installation scheme 2, installation scheme 1 will be used in the following research.

(a)

(b)

The brace stiffness K_b is taken as 0.2 times of the axial stiffness of the tower column unit, and the loss factor η of the VED is taken as 1.4. The ratio of the equivalent energy storage stiffness of the VED to brace stiffness λ is calculated as 0.531 by equation (16), and the value of λ is further varied from 0.491 to 0.631. Based on the modal strain energy method and the complex modal analysis method, the variations of the first additional modal damping ratio ξ₁ with λ are illustrated in Figure 12. It can be found in Figure 12 that when the brace stiffness K_b is a setting value, and the ratio of the equivalent storage of the VED to the brace stiffness is taken as the calculated value of equation (16), the first additional modal damping ratio ξ₁ of the transmission line tower obtained by the complex modal analysis method reaches the maximum value. Note that the first additional modal damping ratio ξ₁ predicted by the complex modal analysis method is greater than that of the modal strain energy method, and the value of the λ corresponding to the first maximum additional modal damping ratio ξ₁ calculated by the complex modal analysis method is less than that of the first maximum additional modal damping ratio ξ₁ calculated by the modal strain energy method. In addition, the first additional modal damping ratio of the transmission line tower can be improved by increasing the bracing stiffness K_b.

(a)

(b)

The variations of the second additional modal damping ratio ξ₂ with λ are further depicted in Figure 13. It is noteworthy that the variation of the second additional modal damping ratio ξ₂ with λ is consistent with that of the first additional modal damping ratio ξ₁ with λ. It means that lower-order vibration control of the transmission line tower can be realized by controlling the first-order modal vibration of the transmission tower. Hence, the influences of the ratio of brace stiffness to tower column unit stiffness α_b and the loss factor η on the first additional modal damping ratio ξ₂ of the transmission line tower are emphatically investigated in the following research.

(a)

(b)

The loss factor η of the VED is taken as 1.4, and the ratio of the equivalent energy storage stiffness of the VED to brace stiffness λ is calculated by equation (16). Based on the modal strain energy method and the complex modal analysis method, the variations of the first additional modal damping ratio ξ₁ with the ratio of brace stiffness to tower column unit stiffness α_b are shown in Figure 14. As shown in Figure 14, the first additional modal damping ratio ξ₁ increases linearly with the increase of the α_b. In addition, the first additional modal damping ratio ξ₁ predicted by the complex modal analysis method is also greater than that of the modal strain energy method.

(a)

(b)

The ratio of brace stiffness to tower column unit stiffness α_b is taken as 0.2, and the ratio of the equivalent energy storage stiffness of the VED to brace stiffness λ is calculated by equation (16). Based on the modal strain energy method and the complex modal analysis method, the variations of the first additional modal damping ratio ξ₁ with the loss factor η of the VED are shown in Figure 15. Note that the first additional modal damping ratio ξ₁ increases linearly with the increase of the η. Consistent with the result of Figure 14, the first additional modal damping ratio ξ₁ predicted by the complex modal analysis method is also greater than that of the modal strain energy method.

(a)

(b)

4. Control Performance of VEDs for Wind-Induced Excitations

The wind load in the vertical direction is applied to the transmission line tower without control and controlled by VEDs, respectively. The basic wind speed at 10 mm elevation is 30 m/s, and the site type is class B. The wind speed corresponding to each elevation is different, and the fluctuating wind speed time history at each height of the transmission line tower is simulated according to the harmonic synthesis method. In ANSYS, the buffeting force-time history is input along the main tower column of the transmission line tower, and the time domain response of the buffeting displacement is calculated by the time history integration method. The first two natural modal damping ratios of the transmission line tower are 0.02. The transmission line tower is subjected to random vibration under fluctuating wind load in the range of 0 s to 500 s.

Figure 16 illustrates the time history response of the displacement of the 481 nodes on the top of the transmission line tower along the wind direction without control and controlled by VEDs. The mean square value of the displacement on the top of the transmission line tower control by VEDs is 0.0091 m, which is 18.9% lower than that of the transmission line tower without control 0.1124 m. The power spectrum density of the displacement response of the transmission line tower without control and controlled by VEDs is shown in Figure 17. Compared with the transmission line tower without control, the transverse bending vibration energy of the transmission line tower control by VEDs presents a significant decrease.

5. Conclusions

This paper investigates the optimization of VEDs for vibration control of a transmission line tower subjected to wind excitations. The mechanical model of the VED-brace system was first established, and the maximum additional modal damping ratio of the transmission line tower attached with VEDs was calculated. Based on the finite element model of a two-circuit transmission line tower with VEDs, the influences of installation positions and parameters of VEDs on the additional modal damping ratio were clarified. In the end, the control performance of VEDs on the transmission line tower subjected to wind excitations was numerically demonstrated. The main conclusions are summarized as follows:(1)The stiffness of the steel brace connected to a VED has a significant effect on the maximum additional modal damping ratio of the VED-brace system provided for the transmission line tower and the optimal parameters of the VED, which indicates that the stiffness of the steel brace cannot be ignored for the refined theoretical analysis and numerical simulation.(2)The installation positions of VEDs dramatically influence the additional modal damping ratio of the transmission line tower. Studies indicate that the first additional modal damping ratio provided by VEDs installed in accordance with installation scheme 1 is greater than that provided by the VED installed in accordance with installation scheme 2. Hence, installation scheme 1 is superior to installation scheme 2. Besides that, the first additional modal damping ratio predicted by the complex modal analysis method is greater than that of the modal strain energy method.(3)The increase of the brace stiffness and the loss factor helps to improve the vibration control performance of the transmission line tower with VEDs. The equivalent additional modal damping ratio provided by VEDs is increased with the brace stiffness and the loss factor, which presents a significant advantage in carrying out the optimal design of VEDs for mitigating tower vibrations.(4)The VEDs present superior control performance on the top displacement of the transmission line tower as well as the transverse bending vibration energy. The mean square value of the displacement on the top of the transmission line tower control by VEDs is 0.0091 m, which is 18.9% lower than that of the transmission line tower without control 0.1124 m.

Data Availability

The data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare no conflicts of interest.

Acknowledgments

This study was sponsored by Hunan Provincial Natural Science Foundation of China (Grant no. 2021JJ50143) and by Hunan Science and Technology Talent Promotion Project in China (Grant no. 2019TJ-Y08), which are greatly acknowledged.

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Copyright

Copyright © 2021 Guoping Huang et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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