Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio
Abstract
:1. Introduction
2. Structure Prototype and Finite Element Model
2.1. Description of the Structural Prototype Layout
2.2. 220 kV Transmission Line Loading
2.3. Non-Linear Dynamic Analysis (NL-DA)
2.3.1. Intensity Measure
2.3.2. Damage Measure
2.3.3. Limit States
2.4. Input Ground Motion Records
2.5. Probabilistic Distribution Function Using Fragility Curve
2.6. Collapse Margin Ratio
2.7. Structural Dynamic Properties
3. Results and Discussion
3.1. Incremental Dynamic Analysis (IDA)
3.2. Fragility and CMR Analysis
4. Conclusions
- (1)
- For the failure mechanism for the structures, the deformation and failure mode for far-field is buckling failure in its frame members. For the near-field case, it is tensile failure with fracture material, which becomes worse when subjected to repetitive aftershock excitation that results in a combination of tensile failure with material fracture and compression buckling at the base of the columns.
- (2)
- From the IDA curves, for both far-field and near-field, repetitive earthquakes are more damaging to the structure than single events; the far-field case results in CP damage state at 1.10 g and the near-field at 0.80 g, while aftershock results in CP damage state at 0.71 g. However, the transmission tower performs far better in the case of far-field ground motions than near-field. It can be concluded that the frame elements of the transmission steel tower suffer significant damages under near-field and repetitive ground motion than under far-field ground motion, despite the fact that the damage probability at far-field ground motion is greater than near-field ground motion before achieving 1.0 g.
- (3)
- From the fragility curves, the occupancy and life safety limit states are considered crucial in monitoring the seismic performance for the possibility of capacity recovery post seismic events. The structure rapidly loses occupancy during near-field and repetitive seismic events and is more life threatening compared to far-field excitations. As long as the intensity does not exceed 2.50 g, the structure can be repaired. When structures are subjected to near-field seismic occurrences, the structures can benefit from repair attempts if the intensity measure is 1.50 or less, and 1.20 g or less in the case of several seismic scenarios. The radar view provides a clear view of the difference between the three seismic scenarios.
- (4)
- From CMR, the rate of collapse for the transmission steel tower is lower under far-field ground motion than under near-field and repetitive ground motions. This is because the CMR for the far-field ground motion is greater than that of the near-field ground motion; the CMR values are 11.67, 6.67, and 4.67 for the far-field, near-field, repetitive ground motions, respectively. When considered as a single event, the analyses show that the transmission steel tower is more likely to collapse than a tower under far-field ground motion excitation and that the tower is more likely to damage during multiple seismic events, demonstrating that the tower can withstand the desired seismic performance or MCE of 0.30 g according to the Lebanese seismic norm. This verifies the accuracy of the results of the IDA and fragility analyses.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Items | Conductor Lines | Overhead Ground Wires |
---|---|---|
Type | AAC (Aluminum Alloy Conductor) | ACS (Aluminum Clad Steel) |
Name | Aster 570 | ASTM |
Section (mm2) | 570.22 | 77.55 |
Overall diameter (mm) | 31.05 | 11.5 |
Unit weight (kg/m) | 1.574 | 0.472 |
Modulus of elasticity (GPa) | 56 | 140 |
Coefficient of linear expansion/°C | 23.0 × 10−6 | 13.9 × 10−6 |
Section | Profile Size (mm) | Unit Weight (N/m) | Area (mm2) |
---|---|---|---|
Peak Legs | L60 × 60 × 5 | 44.83 | 581.9 |
Cage Legs | L120 × 120 × 11 | 195.22 | 2537 |
L150 × 150 × 14 | 310 | 4004 | |
Cage Primary Bracing | L50 × 50 × 5 | 36.99 | 480.3 |
L70 × 70 × 7 | 72.50 | 939.7 | |
L80 × 80 × 7 | 83.28 | 1082 | |
L100 × 100 × 10 | 147.54 | 1900 | |
Cage Horizontal Bracing | L60 × 60 × 5 | 44.83 | 581.9 |
L70 × 70 × 7 | 72.50 | 939.7 | |
L80 × 80 × 7 | 83.28 | 1082 | |
L100 × 100 × 8 | 119.49 | 1551 | |
Top Cross Arm | L60 × 60 × 5 | 44.83 | 581.9 |
L80 × 80 × 10 | 116.35 | 1511 | |
Middle Cross Arm | L70 × 70 × 6 | 62.69 | 812.7 |
L100 × 100 × 10 | 147.54 | 1915 | |
Bottom Cross Arm | L60 × 60 × 6 | 53.17 | 684 |
L80 × 80 × 7 | 83.28 | 1082 | |
Main Legs | L150 × 150 × 14 | 310.00 | 4004 |
L180 × 180 × 16 | 426.74 | 5504 | |
L180 × 180 × 18 | 476.77 | 6191 | |
L200 × 200 × 18 | 531.70 | 6911 | |
L200 × 200 × 20 | 587.91 | 7635 | |
Leg Primary Bracings | L100 × 100 × 8 | 119.49 | 1551 |
L100 × 100 × 10 | 147.54 | 1900 | |
L100 × 100 × 12 | 174.91 | 2271 | |
L120 × 120 × 11 | 195.22 | 2537 | |
Leg Horizontal Bracings | L60 × 60 × 5 | 44.83 | 625 |
L70 × 70 × 6 | 62.69 | 812.7 | |
L80 × 80 × 7 | 83.28 | 1082 | |
Secondary Bracings | L35 × 35 × 3 | 15.70 | 203.7 |
L40 × 40 × 4 | 23.74 | 307.9 | |
L45 × 45 × 4 | 26.98 | 349.3 | |
L60 × 60 × 5 | 44.83 | 581.9 |
Property | Symbol | Value |
---|---|---|
Modulus of Elasticity | E | 199,948 MPa |
Shear Modulus | G | 76,903 MPa |
Poisson’s Ratio | v | 0.3 |
Tensile Yield Strength | Fy | 345 MPa |
Tensile Ultimate Strength | Fu | 448 MPa |
Tower Type | A |
---|---|
Utilization | Suspension |
Utilization limits | Tangent (0–2°) |
Wind span (m)—Max | 420 |
Weight span (m)—Max | 850 |
Weight span (m)—Min | 50 |
Weight/Wind span ratio-Min | 0.83 at 0° |
Max single span (m) | 700 |
Insulator Weight | 70 kg |
Ground Wire Load (V1) | 24 kN |
Transverse Load on Ground Wire (T1) | 10 kN |
Conductor Wire Load (V2) | 21 kN |
Transverse Load on Conductor Wire (T2) | 13.52 kN |
No. | Earthquake | Year | Station | Mw | PGA(g) | PGV (cm/s) | PGD (cm) | Vs30 (m/s) |
---|---|---|---|---|---|---|---|---|
1 | Kern County | 1952 | LA-Hollywood | 6.91 | 0.450 | 117.79 | 30.79 | 308.94 |
2 | Borrego Mtn | 1968 | El Centro Array #9 | 6.80 | 0.499 | 46.49 | 42.18 | 213.44 |
3 | Friuli Italy | 1976 | Codroipo | 5.04 | 0.554 | 61.53 | 7.15 | 249.28 |
4 | Borrego | 1942 | El Centro Array #9 | 6.41 | 0.277 | 37.32 | 4.65 | 213.44 |
5 | Kern County | 1952 | LA—Hollywood | 6.19 | 0.446 | 29.12 | 9.31 | 316.46 |
6 | Friuli Italy | 1976 | Codroipo | 5.99 | 0.368 | 23.75 | 17.60 | 249.28 |
7 | Imperial Valley | 1979 | Delta | 5.61 | 0.294 | 65.45 | 53.12 | 242.05 |
8 | San Fernando | 1976 | Buena Vista | 6.96 | 0.486 | 105.9 | 93.85 | 298.68 |
9 | Whittier Narrows-01 | 1987 | Santa Fe Springs | 5.99 | 0.398 | 23.75 | 1.76 | 288.78 |
10 | Loma Prieta | 1989 | Gilroy Array # | 6.74 | 0.310 | 64.50 | 25.65 | 221.78 |
11 | Sierra Madre | 1991 | Cogswell Dam | 5.61 | 0.297 | 15.01 | 2.050 | 236.84 |
12 | Kobe | 1995 | KJMA | 6.90 | 0.854 | 95.75 | 24.56 | 187.77 |
13 | Northridge-0 | 1994 | LA Dam | 6.69 | 0.576 | 77.09 | 20.10 | 184.79 |
14 | Chi-Chi | 1999 | TCU065 | 7.62 | 0.831 | 129.55 | 93.85 | 335.50 |
15 | Morgan Hill | 1984 | Captiola | 6.74 | 0.444 | 19.01 | 4.07 | 196.42 |
16 | Borah Peak | 1983 | ETR Reactor Bldg | 6.93 | 0.203 | 58.27 | 16.25 | 214.68 |
17 | San Fernando | 1971 | Terminal Island | 6.21 | 0.548 | 40.74 | 16.01 | 301.95 |
18 | Imperial Valley | 1979 | Niland Fire Station | 6.80 | 0.557 | 82.27 | 55.05 | 212.0 |
No. | Earthquake | Year | Station | Mw | PGA(g) | PGV (cm/s) | PGD (cm) | Vs30 (m/s) |
---|---|---|---|---|---|---|---|---|
1 | Kern County | 1952 | Taft Lincoln School | 7.40 | 0.156 | 15.31 | 9.21 | 310.68 |
2 | Tabas, Iran | 1978 | Ferdows | 7.40 | 0.187 | 6.53 | 4.52 | 302.64 |
3 | Victoria, Mexico | 1980 | SAHOP Casa Flores | 6.30 | 0.101 | 7.77 | 2.45 | 242.05 |
4 | N. Palm Springs | 1986 | Hesperia | 6.10 | 0.412 | 2.32 | 0.71 | 198.77 |
5 | Landers | 1992 | Baker Fire Station | 7.30 | 0.124 | 17.34 | 2.28 | 316.46 |
6 | Northridge-01 | 1994 | Huntington Bch-Waikiki | 6.70 | 0.186 | 5.01 | 1.63 | 184.75 |
7 | Whittier Narrows | 1978 | Los Angeles, CA | 6.10 | 0.182 | 63.21 | 25.36 | 193.67 |
8 | Imperial Valley | 1940 | El Centro CA | 6.90 | 0.341 | 33.14 | 101.69 | 213.44 |
9 | Northridge | 1994 | Sun Valley | 6.70 | 0.457 | 22.47 | 51.59 | 301.95 |
10 | Loma Prieta | 1999 | Hollister, CA | 6.94 | 0.252 | 45.14 | 33.23 | 221.78 |
11 | Coma Mendocina | 1992 | Copa Mendocina | 7.01 | 1.400 | 11.36 | 95.23 | 192.05 |
12 | Landers | 1992 | Lucerne | 7.28 | 0.650 | 52.29 | 44.60 | 208.91 |
13 | Mineral Town | 2011 | Central Verginia | 5.74 | 0.094 | 53.64 | 6.67 | 219.31 |
14 | Kocaeli | 1999 | Sakarya | 7.40 | 0.230 | 55.83 | 184.60 | 249.28 |
15 | Chi Chi | 1999 | TCU102 | 7.60 | 0.390 | 65.48 | 193.30 | 335.50 |
16 | Coyote lake | 1979 | Gilroy Array | 5.74 | 0.333 | 27.14 | 4.48 | 202.85 |
17 | Morgan hill | 1984 | Anderson Dam | 6.19 | 0.276 | 29.52 | 6.44 | 192.26 |
18 | Nahanni, Canada | 1985 | Site1 | 6.76 | 1.170 | 36.53 | 4.66 | 317.45 |
Number of Mode | Natural Period (s) | Natural Frequency (Hz) | Deformed Shape |
---|---|---|---|
1 | 1.061 | 0.942 | Translating in Y-axis (Longitudinal) |
2 | 0.789 | 1.267 | Translating in X-axis (Transversal) |
3 | 0.651 | 1.536 | Rotating about Z-axis (Torsion) |
Seismic Scenarios | IMCE (g) | I50% (g) | CMR |
Far-Field | 0.30 | 3.5 | 11.67 |
Near-Field | 0.30 | 2.0 | 6.67 |
Repeated Earthquakes | 0.30 | 1.4 | 4.67 |
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Kassem, M.M.; Beddu, S.; Qi Min, W.; Tan, C.G.; Mohamed Nazri, F. Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio. Appl. Sci. 2022, 12, 1984. https://doi.org/10.3390/app12041984
Kassem MM, Beddu S, Qi Min W, Tan CG, Mohamed Nazri F. Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio. Applied Sciences. 2022; 12(4):1984. https://doi.org/10.3390/app12041984
Chicago/Turabian StyleKassem, Moustafa Moufid, Salmia Beddu, Wong Qi Min, Chee Ghuan Tan, and Fadzli Mohamed Nazri. 2022. "Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio" Applied Sciences 12, no. 4: 1984. https://doi.org/10.3390/app12041984
APA StyleKassem, M. M., Beddu, S., Qi Min, W., Tan, C. G., & Mohamed Nazri, F. (2022). Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio. Applied Sciences, 12(4), 1984. https://doi.org/10.3390/app12041984