Hooke`s Law and Simple Harmonic Motion Name:
... 5. Click Record and record the distance to the bottom of mass hanger from the motion sensor. Stop the data collection. 6. Add an appropriate mass to make the spring stretch about 2 cm and measure the distance to the bottom of mass hanger, again, and record it. 7. Measure the stretches for other adde ...
... 5. Click Record and record the distance to the bottom of mass hanger from the motion sensor. Stop the data collection. 6. Add an appropriate mass to make the spring stretch about 2 cm and measure the distance to the bottom of mass hanger, again, and record it. 7. Measure the stretches for other adde ...
Figure 58: Gravitational potential-energy experiment. • Betty: fixes
... Recall that any material which returns to its equilibrium position/configuration after the removal of an applied force can be considered to possess spring-like properties. • elastic material: a material such that, when displaced from its equilibrium length, L0 , to a length L, and released, experien ...
... Recall that any material which returns to its equilibrium position/configuration after the removal of an applied force can be considered to possess spring-like properties. • elastic material: a material such that, when displaced from its equilibrium length, L0 , to a length L, and released, experien ...
Work (W) done by a constant force F exerted on an object through
... When the net force and direction of motion are in generally the same directions, work is positive and KE is increasing. When the net force and direction of motion are in generally opposite directions, work is negative and KE is decreasing. ♥ Work done by applied force changes potential energy (when ...
... When the net force and direction of motion are in generally the same directions, work is positive and KE is increasing. When the net force and direction of motion are in generally opposite directions, work is negative and KE is decreasing. ♥ Work done by applied force changes potential energy (when ...
ME2 – MECHANICAL COMPONENTS
... Torque springs provide a displacement proportional to the applied torque T(t) = K θ(t) Rotational systems also experience frition similar to translational systems so, respectively, we have viscous, static and Coulomb friction in rotay systems expressed by T(t) = B θ·(t) ...
... Torque springs provide a displacement proportional to the applied torque T(t) = K θ(t) Rotational systems also experience frition similar to translational systems so, respectively, we have viscous, static and Coulomb friction in rotay systems expressed by T(t) = B θ·(t) ...
Newton`s first and second laws
... If it is moving, it will continue to move in a straight line at constant speed. ...
... If it is moving, it will continue to move in a straight line at constant speed. ...
Chapter 2 - Motion in One Dimension
... Newton’s First Law – Law of Inertia • An object at rest will remain at rest – and an object in motion will continue in motion at a constant velocity (Magnitude and Direction) – unless acted upon by a nonzero net external force. ...
... Newton’s First Law – Law of Inertia • An object at rest will remain at rest – and an object in motion will continue in motion at a constant velocity (Magnitude and Direction) – unless acted upon by a nonzero net external force. ...
Chapter 7 – Kinetic energy and work
... Object stationary before and after the lift: W a+W g=0 The applied force transfers the same amount of energy to the object as the gravitational force transfers from the object. ...
... Object stationary before and after the lift: W a+W g=0 The applied force transfers the same amount of energy to the object as the gravitational force transfers from the object. ...
