Battery Energy and Altitude Change

In summary, altitude change can have a significant impact on battery energy due to the thinner air and reduced oxygen levels. Batteries can be used at high altitudes, but their performance may be affected. Lithium-ion batteries are generally considered the best option for high altitude use. Temperature can also affect battery energy at high altitudes, so it is important to keep batteries within their recommended operating temperature range. To conserve battery energy at high altitudes, it is recommended to minimize the use of battery-powered devices and properly maintain and charge batteries.
  • #1
gates040
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Homework Statement



An electric scooter has a battery capable of supplying 120 Wh of energy. If friction forces and other losses acount for 60.0% of energy usage, what altitude change can a rider achieve when driving in hilly terrain, if the rider and scooter have a combined weight of 890N.

Homework Equations



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The Attempt at a Solution



I just don't understand...
 
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  • #2
Any equations or anything that may make it clear to me would be appreciated. I am capable of solving it for myself, so it is not necessary to actually do the problem. Thank you!
 
  • #3


I can provide an explanation for the relationship between battery energy and altitude change. The battery in an electric scooter is responsible for supplying the energy needed to overcome the gravitational potential energy required for an altitude change. In other words, the battery provides the power needed to move the rider and scooter against the force of gravity.

In this scenario, the battery has a capacity of 120 Wh, which means it can supply 120 joules of energy for every hour of use. However, due to friction and other losses, only 40% of this energy (60% loss) is actually used for the altitude change. This means that the usable energy for the altitude change is 48 Wh (120 Wh x 0.4 = 48 Wh).

To calculate the altitude change that can be achieved, we can use the formula for potential energy: PE = mgh, where m is the mass, g is the gravitational acceleration (9.8 m/s²), and h is the altitude change. In this case, the mass is the combined weight of the rider and scooter, which is 890N. We can convert this to kilograms (kg) by dividing by the gravitational acceleration (890N / 9.8 m/s² = 90.8 kg).

Now, we can rearrange the formula to solve for h: h = PE / mg. Plugging in the values, we get h = (48 Wh x 3600 s) / (90.8 kg x 9.8 m/s²) = 197.9 meters. This means that the rider can achieve an altitude change of 197.9 meters when driving in hilly terrain.

In summary, the usable energy from the battery, combined with the weight of the rider and scooter, determines the altitude change that can be achieved. In real-world scenarios, other factors such as wind resistance and road conditions may also affect the energy usage and altitude change.
 

1. How does altitude change affect battery energy?

Altitude change can have a significant impact on battery energy. As altitude increases, the air becomes thinner, which means there is less oxygen available for combustion in the battery. This can cause a decrease in battery performance and overall energy output.

2. Can batteries be used at high altitudes?

Yes, batteries can be used at high altitudes. However, their performance may be affected due to the thinner air and reduced oxygen levels. It is important to consider the altitude when choosing a battery for a specific application.

3. What types of batteries are best suited for high altitude use?

Lithium-ion batteries are generally considered the best option for high altitude use. They have a high energy density and are not affected as much by changes in altitude compared to other battery types. However, it is still important to consider the specific application and altitude when choosing a battery.

4. How does temperature at high altitudes affect battery energy?

Temperature can also have a significant impact on battery energy at high altitudes. As temperatures decrease, battery performance and energy output may also decrease. It is important to keep batteries within their recommended operating temperature range to maintain optimal performance.

5. How can battery energy be conserved at high altitudes?

One way to conserve battery energy at high altitudes is to minimize the use of battery-powered devices. This can be achieved by using energy-efficient devices and turning them off when not in use. It is also important to properly maintain and charge batteries to ensure optimal performance at high altitudes.

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