TS
T.F.N. Sluiter
info
Please Note
<p>This page displays the records of the person named above and is not linked to a unique person identifier. This record may need to be merged to a profile.</p>
2 records found
1
Master thesis
(2021)
-
T.F.N. Sluiter, P.H.A.J.M. van Gelder, R.C. Lanzafame, A.B. Faragau, D.A. de Loor, I.F. de Graaf
The Dutch government provides a calculation method to determine the risks to society outside the boundaries of institutions handling Dangerous Goods (the risk affecting External Safety). The current method to calculate the risk affecting External Safety for train marshalling yards is deterministic, outdated, and not transparent. This thesis aims to improve the calculation method regarding rear-end collisions in automated marshalling. It provides a reliability-based approach to the study case Kijfhoek and uses a multi-body dynamic model to simulate the collisions. A Monte Carlo simulation is performed implementing over twenty-five parameters to determine the probability of damage in case of a rear-end collision. From the results, a simplified method is designed to assess the probability of damage to the wagon’s structure. This method uses a newly found relation to determine the absorbed energy at the impact interface in case of a collision. Furthermore, the simplified method reduced the calculation to five parameters and an analytically solvable Limit State function. A first-order reliability method shows that the impact velocity is the single most important parameter in determining the probability of damage.
The simplified method also allows for site-specific values and gives insight into the system and the most important parameters. It is recommended that this method, to determine damage to especially tank wagons in rear-end collisions, is used to improve the existing calculation method for determining the risk affecting External Safety.
...
The simplified method also allows for site-specific values and gives insight into the system and the most important parameters. It is recommended that this method, to determine damage to especially tank wagons in rear-end collisions, is used to improve the existing calculation method for determining the risk affecting External Safety.
...
The Dutch government provides a calculation method to determine the risks to society outside the boundaries of institutions handling Dangerous Goods (the risk affecting External Safety). The current method to calculate the risk affecting External Safety for train marshalling yards is deterministic, outdated, and not transparent. This thesis aims to improve the calculation method regarding rear-end collisions in automated marshalling. It provides a reliability-based approach to the study case Kijfhoek and uses a multi-body dynamic model to simulate the collisions. A Monte Carlo simulation is performed implementing over twenty-five parameters to determine the probability of damage in case of a rear-end collision. From the results, a simplified method is designed to assess the probability of damage to the wagon’s structure. This method uses a newly found relation to determine the absorbed energy at the impact interface in case of a collision. Furthermore, the simplified method reduced the calculation to five parameters and an analytically solvable Limit State function. A first-order reliability method shows that the impact velocity is the single most important parameter in determining the probability of damage.
The simplified method also allows for site-specific values and gives insight into the system and the most important parameters. It is recommended that this method, to determine damage to especially tank wagons in rear-end collisions, is used to improve the existing calculation method for determining the risk affecting External Safety.
The simplified method also allows for site-specific values and gives insight into the system and the most important parameters. It is recommended that this method, to determine damage to especially tank wagons in rear-end collisions, is used to improve the existing calculation method for determining the risk affecting External Safety.
Due to the high cost of long spanned bridges or deep tunnels, the interest into a submerged floating tunnel (SFT) has reemerged. In the last twenty years many studies on the SFT have been performed. This report investigates the interaction between a single vehicle, moving at constant velocity, and the SFT. The research is limited to the dynamic response, of both vehicle and tunnel, in only the vertical direction. The SFT is moored to the bed floor and is further kept in position by the buoyance force.
The main question to be answered is: Does the vehicle’s inertia, the design of the SFT (i.e., the length of the tunnel) or the vehicle parameters, because of this dynamic loading, play a significant role in the Ultimate Limit State of the tunnel or the Service Limit State for passenger. ...
The main question to be answered is: Does the vehicle’s inertia, the design of the SFT (i.e., the length of the tunnel) or the vehicle parameters, because of this dynamic loading, play a significant role in the Ultimate Limit State of the tunnel or the Service Limit State for passenger. ...
Due to the high cost of long spanned bridges or deep tunnels, the interest into a submerged floating tunnel (SFT) has reemerged. In the last twenty years many studies on the SFT have been performed. This report investigates the interaction between a single vehicle, moving at constant velocity, and the SFT. The research is limited to the dynamic response, of both vehicle and tunnel, in only the vertical direction. The SFT is moored to the bed floor and is further kept in position by the buoyance force.
The main question to be answered is: Does the vehicle’s inertia, the design of the SFT (i.e., the length of the tunnel) or the vehicle parameters, because of this dynamic loading, play a significant role in the Ultimate Limit State of the tunnel or the Service Limit State for passenger.
The main question to be answered is: Does the vehicle’s inertia, the design of the SFT (i.e., the length of the tunnel) or the vehicle parameters, because of this dynamic loading, play a significant role in the Ultimate Limit State of the tunnel or the Service Limit State for passenger.