If the distance from the water source to the water wheel is reduced, the rotation speed of the wheel would likely increase. This is because the water would flow more freely and quickly to the wheel, providing a greater volume and pressure of water that can drive the wheel. Consequently, the increased water flow would enhance the wheel's ability to rotate faster, assuming other factors, such as the wheel's design and water flow rate, remain constant.
tangential speed is directly proportional to rotational speed at nay fixed distance from the axis of rotation
Speed = Distance/TimeTime = Distance/SpeedDistance = Speed*TimeSpeed = Distance/TimeTime = Distance/SpeedDistance = Speed*TimeSpeed = Distance/TimeTime = Distance/SpeedDistance = Speed*TimeSpeed = Distance/TimeTime = Distance/SpeedDistance = Speed*Time
Time = (distance) divided by (speed) Distance = (speed) multiplied by (time) Speed = (distance) divided by (time)
D= Distance S= Speed T= Time Speed = Distance/Time Distance = Speed x Time Time Taken = Distance/Speed
The relationship between distance, time, and speed is described by the formula: Speed = Distance / Time. This means that speed is calculated by dividing the total distance traveled by the time taken to travel that distance. Conversely, you can rearrange the formula to find distance (Distance = Speed × Time) or time (Time = Distance / Speed). This formula applies to constant speed and is fundamental in physics and everyday calculations.
tangential speed is directly proportional to rotational speed at nay fixed distance from the axis of rotation
No dependency, when measured on Earth.
Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.
Linear speed cannot be converted to rotational speed without knowledge about the distance from the axis of rotation.
At any distance from the axis of rotation, the linear speed of an object is directly proportional to the rotational speed. If the linear speed increases, the rotational speed also increases.
The circumference around the Earth at different latitudes varies, from 40,075 km at the equator, to 26,291 km at 49° latitude, to 0km at the axis of rotation (i.e. the North and South poles). Thus, as the Earth spins around it's axis, different latitudes will cover different distances within the same time frame. And since speed (and velocity) are calculated by dividing distance by time, the speed (and velocity) will therefore decrease as you approach the poles.
Since everyone and everything on Earth does so anyway, nothing.
The linear speed of a rotating object depends on its angular speed (how fast it rotates) and the distance from the axis of rotation (the radius). Linear speed is calculated as the product of the angular speed and the radius.
Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.Torque is a force times a distance (the distance from the rotation axis where the force is applied). The angle at which the force is applied can also play a role. It is not directly related to speed.
When speed increases with the distance between cars, there is a greater risk of accidents due to reduced reaction time and increased stopping distance. Drivers may not be able to brake in time if the distance is too large, leading to rear-end collisions or other accidents. It is important to maintain a safe following distance to allow for proper reaction time in case of sudden stops or changes in traffic.
If the distance increases but the time decreases, the average speed of the object would increase. This is because speed is calculated as distance divided by time, so when distance increases and time decreases, the ratio of distance to time increases, resulting in a higher average speed.
The relevant formula here is:centrifugal acceleration = omega squared x radiusomega (the angular speed) doesn't change in this formula (for the situation under consideration), but "radius", the distance from the axis of rotation, does.