1 Introduction
2 Typical B-type Subway Train and Energy-absorbing Devices
3 One-dimensional Train Collision Dynamics Model
3.1 Model Building
Structure name | Modeling method | |
---|---|---|
Dynamics model | Finite element model | |
Track | 1. Hexahedral elements are applied. 2. #MAT 20 material is assigned. 3. All degrees of freedom are restricted. | 1. Hexahedral elements are applied. 2. #MAT 20 material is assigned. 3. All degrees of freedom are restricted. 4. The actual rail profile is considered. |
Carbody | 1. Hexahedral elements are applied. 2. #MAT 20 material is assigned. 3. The translational freedom along with the train movement is retained and other degrees of freedom are restricted. 4. The material density is adjusted to achieve the weight change. | 1. Mainly quadrilateral shell elements and triangular elements in local irregular locations are applied. 2. Hexahedral elements for structures with a thickness above 20 mm are defined. 3. The element size is controlled within 15–20 mm. 4. #MAT 24 elastoplastic material is assigned. |
Bogie | 1. The bogie is not modeled. 2. The equivalent weight is added to the carbody. | 1. Quadrilateral shell elements are used. 2. The bogie-frame, wheel-set, axle box, gearbox, anti-rolling torsion bar, and traction rod seat are modeled separately. 3. #MAT 20 material is assigned; 4. Joint elements are added to simulate the relative motion among different parts; 5. Discrete beams are applied with #MAT 67 material to simulate the primary and secondary suspensions, considering the actual stiffness and damping. |
Anti-climbing energy-absorbing device, semi-automatic and semi-permanent couplers | 1. Discrete beams are applied with #MAT S08 material. 2. The corresponding curves in Figure 2 are considered as the input curves. | 1. Quadrilateral shell elements are used for the structures and the #MAT 20 material is assigned. 2. Joint elements are added to simulate the relative motion between different parts. 3. Discrete beam elements are used with #MAT S08 material to simulate the mechanical characteristics, the corresponding curves in Figure 2 are considered as the input curves. |
Wheel-rail contact | 1. Discrete beam elements are applied with #MAT S03 material. 2. The equivalent friction force is input; the friction coefficient is considered as 0.008 [19]. | 1. Surface to surface contact between the wheel and rail is defined. 2. The friction coefficient is considered as 0.008 [19]. |
Vehicle contact | 1, Contact between the vehicles is not considered. | 1. Self-contact between the vehicles is defined. 2. The friction coefficient is considered as 0.15 [32]. |
3.2 Model Validation
Collision Scenario | Item | Boundary condition |
---|---|---|
1 | Collision mass 1 | The weight of the Tc car is 34.08 t, the weight of the Mp/M car is 36.26 t, and the total weight of the six-car marshaling train is 213.2 t. |
Collision velocity | 25 km/h | |
Wheel-rail friction | The wheel/rail friction coefficient is set as 0.008 [19]. | |
2 | Collision mass 2 (work order plus six persons standing per square meter) | The weight of the Tc car is 46.56 t, the weight of the Mp/M car is 50.24 t, and the total weight of the six-car marshaling train is 294.08 t. |
Collision velocity | 15 km/h | |
Wheel-rail friction | The wheel/rail friction coefficient is set as 0.008 [19]. |
4 Vehicle Design Parameters and Train Crashworthiness Criteria
4.1 Definition of Vehicle Design Parameters
4.2 Definition of Train Crashworthiness Evaluation Criteria
5 Influence of the Empty Stroke D on Train Collision Response
5.1 Influence on the Response of the Energy-absorbing Device
Empty stroke D(mm) | Compression displacement (mm) | Energy absorption (kJ) | |||||
---|---|---|---|---|---|---|---|
Collision Interface S1-M1 Semi-automatic coupler | Collision Interface S1-M1 Anti-climbers | Collision Interface M1-M2 | Collision Interface M2-M3 | Collision Interface S1-M1 | Collision Interface M1-M2 | Collision Interface M2-M3 | |
20 | 353 | 223.7 | 320.77 | 342.6 | 599.78 | 281.48 | 255.46 |
23.75 | 353 | 233.95 | 312.86 | 335.86 | 612.57 | 273.68 | 250.07 |
27.5 | 353 | 239.15 | 315.56 | 324.94 | 619.05 | 275.95 | 241.33 |
31.25 | 353 | 243.2 | 320.96 | 312.42 | 624.13 | 281.45 | 231.31 |
35 | 353 | 250 | 320.17 | 302.36 | 632.62 | 280.84 | 223.27 |
38.75 | 353 | 252.65 | 328.56 | 288.64 | 635.98 | 288.94 | 212.3 |
42.5 | 353 | 261.05 | 324.62 | 279.86 | 646.46 | 284.9 | 205.26 |
46.25 | 353 | 262.6 | 335.12 | 265.16 | 648.4 | 295.66 | 193.5 |
50 | 353 | 269.75 | 333.71 | 255.56 | 657.36 | 294.08 | 185.84 |
Relative change (%) | – | 20.59 | 4.03 | − 25.41 | 9.60 | 4.48 | − 27.25 |
5.2 Influence on the Vehicle Response
Empty stroke D(mm) | Maximum collision instantaneous acceleration (g) | |||||
---|---|---|---|---|---|---|
Vehicle M1 | Vehicle M2 | Vehicle M3 | Vehicle M4 | Vehicle M5 | Vehicle M6 | |
20 | 2.8739 | 1.3181 | 0.9199 | 0.7526 | 1.0643 | 1.1362 |
23.75 | 2.8739 | 1.3181 | 0.9199 | 0.7526 | 1.0643 | 1.1362 |
27.5 | 2.8739 | 1.3181 | 0.9199 | 0.7519 | 1.0582 | 1.1358 |
31.25 | 2.8739 | 1.3181 | 0.9199 | 0.7512 | 1.057 | 1.1357 |
35 | 2.8739 | 1.3181 | 0.9199 | 0.7509 | 1.0568 | 1.1355 |
38.75 | 2.8739 | 1.3181 | 0.9199 | 0.7504 | 1.0549 | 1.1351 |
42.5 | 2.8739 | 1.3181 | 0.9199 | 0.7503 | 1.055 | 1.1352 |
46.25 | 2.8739 | 1.3181 | 0.9199 | 0.7498 | 1.0532 | 1.1351 |
50 | 2.8739 | 1.3181 | 0.9199 | 0.7491 | 1.052 | 1.1349 |
Relative change (%) | 0 | 0 | 0 | − 0.47 | − 1.16 | − 0.11 |
5.3 Influence on the Responses of TS and TAMA
Empty stroke D (mm) | TS (mm) | TAMA (g) |
---|---|---|
20 | 1360.236 | 1.3442 |
23.75 | 1355.836 | 1.3442 |
27.5 | 1352.722 | 1.343 |
31.25 | 1349.562 | 1.3426 |
35 | 1345.454 | 1.3425 |
38.75 | 1342.633 | 1.3421 |
42.5 | 1338.285 | 1.3421 |
46.25 | 1335.462 | 1.3417 |
50 | 1331.535 | 1.3413 |
Relative change % | − 2.11 | − 0.22 |
6 Influence of the Vehicle Design Collision Weight M on Train Collision Response
6.1 Influence on the Response of the Energy-absorbing Device
Vehicle designing weight M (t) | Compression displacement (mm) | Energy absorption (kJ) | |||||
---|---|---|---|---|---|---|---|
Collision interface S1-M1 Semi-automatic coupler | Collision interface S1-M1 Anti-climbers | Collision interface M1-M2 | Collision interface M2-M3 | Collision interface S1-M1 | Collision interface M1-M2 | Collision interface M2-M3 | |
30 | 353 | 205.5 | 292.43 | 277.48 | 576.99 | 253.19 | 203.36 |
30.75 | 353 | 216.75 | 305.15 | 271.47 | 591.05 | 265.31 | 198.53 |
31.5 | 353 | 225.7 | 326.45 | 272.37 | 602.23 | 286.73 | 199.25 |
32.25 | 353 | 233.95 | 333.08 | 287.18 | 612.57 | 293.23 | 211.13 |
33 | 353 | 250 | 320.17 | 302.36 | 632.62 | 280.84 | 223.27 |
33.75 | 353 | 260.15 | 325.62 | 320.21 | 645.31 | 286.47 | 237.57 |
34.5 | 353 | 266.6 | 350.97 | 317.13 | 653.37 | 311.76 | 235.07 |
35.25 | 353 | 281.7 | 342.35 | 326.71 | 672.25 | 303.12 | 242.74 |
36 | 353 | 292.15 | 349.24 | 344.95 | 685.33 | 310.13 | 257.4 |
Relative change (%) | – | 42.17 | 19.43 | 24.32 | 18.78 | 22.49 | 26.57 |
6.2 Influence on the Vehicle Response
Vehicle designing weight M (t) | Maximum collision instantaneous acceleration (g) | |||||
---|---|---|---|---|---|---|
Vehicle M1 | Vehicle M2 | Vehicle M3 | Vehicle M4 | Vehicle M5 | Vehicle M6 | |
30 | 3.1614 | 1.4469 | 1.0037 | 0.8259 | 1.1684 | 1.2459 |
30.75 | 3.0842 | 1.4126 | 0.9852 | 0.8016 | 1.1396 | 1.2201 |
31.5 | 3.0108 | 1.3797 | 0.9572 | 0.7903 | 1.112 | 1.1958 |
32.25 | 2.9407 | 1.3487 | 0.931 | 0.7579 | 1.0767 | 1.1789 |
33 | 2.8739 | 1.3181 | 0.9199 | 0.7509 | 1.0568 | 1.1355 |
33.75 | 2.8101 | 1.2891 | 0.8961 | 0.7327 | 1.0422 | 1.1156 |
34.5 | 2.749 | 1.2618 | 0.8718 | 0.7247 | 1.0204 | 1.0898 |
35.25 | 2.6905 | 1.2349 | 0.8543 | 0.6951 | 0.99 | 1.0721 |
36 | 2.6345 | 1.2087 | 0.8438 | 0.6893 | 0.9784 | 1.0415 |
Relative change (%) | − 16.67 | − 16.46 | − 15.93 | − 16.54 | − 16.26 | − 16.41 |
6.3 Influence on the Responses of TS and TAMA
Vehicle designing weight M (t) | TS (mm) | TAMA (g) |
---|---|---|
30 | 1248.459 | 1.442 |
30.75 | 1266.546 | 1.409 |
31.5 | 1297.41 | 1.378 |
32.25 | 1327.219 | 1.344 |
33 | 1345.454 | 1.316 |
33.75 | 1378.996 | 1.290 |
34.5 | 1407.421 | 1.263 |
35.25 | 1423.718 | 1.234 |
36 | 1459.425 | 1.212 |
Relative change (%) | 16.9 | −15.95 |
7 Coupling Influence and Correlation Analysis of the Design Parameters
Tests | Vehicle design parameters | Compression displacement (mm) | Maximum collision instantaneous acceleration (g) | TS(mm) | TAMA (g) | ||||
---|---|---|---|---|---|---|---|---|---|
D(mm) | M(t) | Collision interface S1-M1 Anti-climber | Collision interface M1-M2 | Collision interface M2-M3 | Vehicle M1 | Vehicle M2 | |||
1 | 20 | 35 | 243.95 | 363.90 | 363.58 | 3.07 | 1.22 | 1444.68 | 1.33 |
2 | 50 | 31 | 238.75 | 335.77 | 213.52 | 3.29 | 1.42 | 1260.95 | 1.47 |
3 | 37 | 32 | 233.05 | 332.46 | 276.86 | 3.18 | 1.45 | 1315.22 | 1.44 |
4 | 40 | 30 | 209.65 | 302.99 | 258.03 | 3.42 | 1.56 | 1243.66 | 1.54 |
5 | 23 | 33 | 231.9 | 314.43 | 337.22 | 3.15 | 1.29 | 1356.71 | 1.39 |
6 | 33 | 34 | 256.55 | 329.83 | 330.28 | 3.04 | 1.26 | 1389.72 | 1.34 |
7 | 43 | 35 | 282.15 | 365.24 | 302.94 | 2.91 | 1.3 | 1422.93 | 1.31 |
8 | 30 | 36 | 288.1 | 340.71 | 362.15 | 2.87 | 1.19 | 1464.29 | 1.27 |
9 | 47 | 33 | 263.55 | 335.85 | 262.78 | 3.08 | 1.38 | 1334.74 | 1.39 |
10 | 27 | 31 | 207.95 | 313.85 | 288.29 | 3.33 | 1.37 | 1283.35 | 1.47 |
Vehicle design parameters | Energy-absorbing devices compression displacement | Vehicle maximum collision instantaneous acceleration | TS | TAMA | |||
---|---|---|---|---|---|---|---|
Collision interface S1-M1 Anti-climber | Collision interface M1-M2 | Collision interface M2-M3 | Vehicle M1 | Vehicle M2 | |||
D | 0.183 | 0.034 | − 0.819 | 0.132 | 0.554 | − 0.446 | 0.307 |
M | 0.851 | 0.740 | 0.790 | − 0.962 | − 0.898 | 0.991 | − 0.991 |
8 Multi-objective Optimization and Decision Making
8.1 Formulation of the Surrogate Model
Accuracy evaluation criteria | ARE | RSME | R2 |
---|---|---|---|
TS | 0.066 | 0.073 | 0.952 |
TAMA | 0.022 | 0.025 | 0.993 |
8.2 Multi-objective Optimization
8.3 Multi-objective Decision Making
Crashworthiness criterion | Entropy value | Difference coefficient | Weight coefficient |
---|---|---|---|
TS | 2.30111 | − 1.30111 | 0.50003 |
TAMA | 2.30093 | − 1.30093 | 0.49997 |
Calculation method | D(mm) | M (t) | TS (mm) | TAMA (g) |
---|---|---|---|---|
Surrogate model | 50 | 32.4 | 1307.5 | 1.4 |
Collision dynamics model | 50 | 32.4 | 1318.96 | 1.36 |
Relative error (%) | – | – | 0.87 | 3.01 |