they have a braking system
No, the roller coaster is not the only example of a closed energy system.
allows you to create your own Roller Coaster park
As far as launched coasters go, there are typically fins on the side of the coaster car. These fins pass through slits on the side of the track that have a magnetic field in them. The magnetic push or pull is what causes the train to move.
Mechanical energy is used on the chains that pull the roller coaster cars up the tallest incline, which is typically located at the start of the track. Mechanical energy is also used in the braking system that slows the cars to a stop at the end of the track.
Usually by An automatic brake system controlled by computers.
hydraulic system of road roller with schematic
Coaster brakes are a type of braking system on a bike that are activated by pedaling backward. They differ from other types of braking systems, such as hand brakes, which are activated by squeezing levers on the handlebars. Coaster brakes are typically found on cruiser bikes and are known for their simplicity and ease of use.
the safety bars that hold you in, the rails & the Adv. Brake system
One conservation of energy practice problem involves a roller coaster at the top of a hill. If the roller coaster has a potential energy of 1000 J at the top of the hill and a kinetic energy of 200 J at the bottom, what is the total mechanical energy of the roller coaster system? To solve this problem, you can use the conservation of energy principle, which states that the total mechanical energy of a system remains constant if only conservative forces are acting on it. In this case, the roller coaster system only experiences gravitational potential energy and kinetic energy. At the top of the hill, the roller coaster has 1000 J of potential energy. At the bottom, it has 200 J of kinetic energy. Therefore, the total mechanical energy of the roller coaster system is: Total mechanical energy Potential energy Kinetic energy Total mechanical energy 1000 J 200 J Total mechanical energy 1200 J So, the total mechanical energy of the roller coaster system is 1200 J. This practice problem helps illustrate how energy is conserved in a system and how potential and kinetic energy are related.
You're not giving quite enough information. At the moment you are interested in, is the roller coaster moving freely on the track, or is it under the control of a cog or other system? Is the roller coaster on its way down an incline, or on its way up?
I would suggest you to change your system. That might be weaker to run this game!