russ_watters said:Welcome to PF!
The seat belt is connected to the car in three places. The angle of the belt at the connection won't be exactly in the direction the car is moving, so one would have to calculate the force each point can take, but I don't think it will be too far off from 8kn per connection.
Pkruse said:The calculations do not model reality well. There is no way that the structure of the automobile can transmit 60 g to the person. It will start yielding and breaking up, which absorbs much energy and minimizes loads transmitted to the person. Anything over 40 g is not survivable under any conditions. In most cases it will take less than that to kill. That is why the USAF puts a 40 g survivability requirement on the crew station of all their aircraft.
AlephZero said:Don't forget that a crash dummy (just like a human) is not a rigid body. Some of the energy will be absorbed in deforming it.
Well, I'm not sure. Because the arms, legs and head are free to move/pivot, they decelerate after the torso, so they may not affect the maximum force felt by the belt. It isn't a simple problem to model.ataskaita said:russ_watters, you wrote about 3 points of seatbelt tensionning, but in such case, as then the whole body is restrained by the seat belt we get 80 kg * 600 m/s^2, which is 48KN. Concerning the angle i don't know if it matters if the whole weight of the driver is restrained by the belt. And as i understand belt force is measured by cutting the belt in two and connecting it again with a force meter (well not exactly, but you get the point).
Again, any thoughts, maybe I'm missing something?
Seat belt force mismatch refers to the difference between the predicted force exerted by a seat belt during a crash and the actual force measured in test data. It is a common phenomenon in safety testing and can have implications for the effectiveness of seat belts in protecting passengers.
There are several factors that can contribute to seat belt force mismatch, including variations in seat belt design, materials, and installation. Additionally, the dynamics of a crash can affect the force exerted on the seat belt, leading to differences between real-world crashes and controlled testing scenarios.
Seat belt force mismatch is typically measured by comparing the predicted force from computer simulations or calculations to the actual force measured in crash tests. This can be done using specialized equipment such as load cells placed on the seat belt or by analyzing video footage of the crash.
If there is a significant difference between predicted and measured seat belt forces, it may indicate that the seat belt is not performing as intended and may not adequately protect passengers in a crash. This can have serious safety implications and may require further testing and design improvements.
To reduce seat belt force mismatch, manufacturers and researchers can use advanced simulation tools and conduct more comprehensive real-world testing. This can help to identify areas for improvement in seat belt design and ensure that they are effective in protecting passengers during crashes.