ANSWER: I'm assuming by "mousetrap" car, you mean small car. Probably pretty obvious at that point that your car would have a.....small mass.
The car with a mass of 1500 kg has more inertia than the car with a mass of 900 kg. Inertia is directly proportional to mass, so the car with greater mass will have greater inertia.
When moving the 1500kg has more inertia.
If the mass of a car is 1200 kg, and the mass of the driver is 65 kg, the total combined mass of the car and driver expressed with the correct number of significant figures is 1265 kg.
If the mass of a car is 1200 kg, and the mass of the driver is 65 kg, the total combined mass of the car and driver expressed with the correct number of significant figures is 1265 kg.
because the force the drives it
Yes, momentum depends on both mass and velocity. So, a slower car with a much larger mass could potentially have more momentum than a faster car with less mass.
car mass is heaveir cars with that you have more handling
When moving the 1500kg has more inertia.
This is because the work done in order to move the toy car is smaller than that of the car with the added mass, and so the battery will have to work harder to move the toy car with the mass added
To determine the mass of the car, we would need to know the acceleration of the car. Using Newton's second law (F = ma), we can rearrange the equation to find mass (m = F/a) if we know the acceleration. Without the acceleration value, we cannot calculate the mass of the car based solely on the net force.
The greater the mass of the car and its occupants the longer the stopping distance that is required for the vehicle. Stopping distance is calculated by taking into account car mass and reaction time in braking