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Tension.

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Presentation on theme: "Tension."— Presentation transcript:

1 Tension

2 Tension occurs within a material that is being pulled or stretched
Tension occurs within a material that is being pulled or stretched. It is an internal force that acts at all points along a rope (string, chain, etc) in both directions.

3 If m1 is pulled to the right by a force of 40.0 N find:
Consider two carts attached by a rope being pulled along a flat surface. (Friction is negligible.) If m1 is pulled to the right by a force of 40.0 N find: The acceleration of the carts. The tension in the string connecting them. m2 = 6.0 kg m1 = 4.0 kg

4 The acceleration can be found using the net force equation for the entire system: NOTE: tension cancels out of the total Fnet equation m2 = 6.0 kg m1 = 4.0 kg

5 Since it cancels out of the total Fnet equation, to solve for tension we will only consider the forces acting on one mass. NOTE: Since tension acts on both masses equally we can use either mass. m2 = 6.0 kg m1 = 4.0 kg

6 Consider two equal masses hanging from a pulley
Consider two equal masses hanging from a pulley. Diagram the forces acting on the entire system. With pulley problems it is sometime easier to “unfold” the rope as shown. m1 m2

7 m1 m2 Write the net force equation including ALL forces acting on the system. Again tension acts in both directions along the rope so it cancels out of the equation.

8 The acceleration of the system. The tension in the string.
Ex: The two masses shown hanging from a frictionless pulley are released at rest. Find The acceleration of the system. The tension in the string. 6.0 kg 4.0 kg NOTES: When solving for acceleration of the whole system we consider mtotal. When finding T we only use one mass.

9 The acceleration of the masses. The tension in the rope.
Ex: A mass on a frictionless table is attached to a hanging mass over a frictionless pulley as shown. Find: The acceleration of the masses. The tension in the rope. 8.0 kg 6.0 kg

10 The acceleration of the masses. The tension in the rope.
Ex2: If the same system has a friction force of 25 N acting on the 8.0 kg mass find: The acceleration of the masses. The tension in the rope. 8.0 kg 6.0 kg

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