Lol211
In this case, calculate energy (work) as force times distance.
Wiki User
โ 14y agoThe work done can be calculated using the formula: Work = Force ร Distance Work = 8 N ร 13 m Work = 104 joules Therefore, you have completed 104 joules of work.
Vector quantities can be described using units such as meters, kilometers, newtons, or pounds-force for displacement or force; meters per second or kilometers per hour for velocity; and newtons or pounds-force for acceleration.
To calculate the work done, you would multiply the force applied (2.5 N) by the distance moved (7 m). Work = Force x Distance. So, the work done to move the dresser 7 meters with a force of 2.5 newtons would be 17.5 joules.
Force can be measured using a dynamometer or force sensor, which typically measures in units of Newtons. Distance can be measured using tools such as rulers, tape measures, or laser distance meters, with units typically in meters or centimeters. Multiplying force by distance gives work, a measure of energy transfer.
Vector quantities can be described using units such as meters (m) for displacement, meters per second (m/s) for velocity, Newtons (N) for force, and Newtons per coulomb (N/C) for electric field.
The power required to move the chair can be calculated using the formula Power = force x distance รท time. Plugging in the values: P = 51 N x 5 m รท 15 s = 17 Watts. Therefore, it would take approximately 17 Watts of power to move the chair 5 meters in 15 seconds using a force of 51 Newtons.
Vector quantities can be described using units such as meters, kilometers, newtons, or pounds-force for displacement or force; meters per second or kilometers per hour for velocity; and newtons or pounds-force for acceleration.
To calculate the work done, you would multiply the force applied (2.5 N) by the distance moved (7 m). Work = Force x Distance. So, the work done to move the dresser 7 meters with a force of 2.5 newtons would be 17.5 joules.
Force can be measured using a dynamometer or force sensor, which typically measures in units of Newtons. Distance can be measured using tools such as rulers, tape measures, or laser distance meters, with units typically in meters or centimeters. Multiplying force by distance gives work, a measure of energy transfer.
Vector quantities can be described using units such as meters (m) for displacement, meters per second (m/s) for velocity, Newtons (N) for force, and Newtons per coulomb (N/C) for electric field.
The pressure exerted by the book on the table can be calculated using the formula: pressure = force/area. In this case, force = 9 Newtons and area = 0.3 square meters. Therefore, the pressure exerted by the book on the table is 30 Pascals (Pa).
The power required to move the chair can be calculated using the formula Power = force x distance รท time. Plugging in the values: P = 51 N x 5 m รท 15 s = 17 Watts. Therefore, it would take approximately 17 Watts of power to move the chair 5 meters in 15 seconds using a force of 51 Newtons.
Work done is equal to Force multiplied by distance:Wd = FxdWd = 324x3Work done = 972 Joules.
Ex: During a softball game, a 0.2kg softball is hit by a bat. If the net force exerted on the softball by the bat is 300N (Newton's), what is the softball's acceleration?0.2kg is mass, so you would take 0.2 divided by 300=1,500... your welcome smarty
If you mean force (not forse) then you measure it using newtons.
The unbalanced force required to accelerate the 1500 kg race car at 3.0 meters per second squared is 4500 Newtons. This is calculated using the formula: force (N) = mass (kg) x acceleration (m/s^2).
The work done to push the carriage with a force of 2 Newtons for a distance of 60 meters is 120 Joules. Work is calculated using the formula: Work = Force x Distance. Therefore, 2 N x 60 m = 120 J.
F = M A In order for a 40-kg mass to accelerate at 2 meters/sec2 , a force of (40 x 2) = 80 newtons has to come from somewhere. That force is what produces that acceleration.