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Chapter 5: Q5Q (page 206)

Question: Tarzan swings from a vine. When he is at the bottom of his swing, as shown in Figure 5.63, which is larger in magnitude: the force by the Earth on Tarzan, the force by the vine (a tension force) on Tarzan, or neither (same magnitude)? Explain how you know this.

Short Answer

Expert verified

Answer

The vine's tension force is greater than the gravitational force.

Step by step solution

01

Definition of the tension force

Tension force is the type of force generated when a load is applied directed away from one or more ends of a material, usually to the cross-section of the material. A tension force is also referred to as a pulling force.

02

Representation of the diagram

As Tarzan swings, the net force acting on him at the bottom of the swing acts in the direction of the rate of change of momentum, which is upward.

Tarzan's veins exert a stronger upward force than their veins exert a downward force. Tarzan must use this upward force to drive himself upward.

The free body diagram for the given situation is shown in below figure,

Here mgis the gravitation force acting on the person, Tis the tension force offered

by vine, and Fcis the centripetal force.

03

Applying the Newton’s second law

Write the net force acting on the Tarzan, according to Newton's second law of motion.

Fc=T-mg

Reorganize the above equation to obtainT.

T=Fc+mg

Thus, the vine's tension force is greater than the gravitational force.

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Most popular questions from this chapter

An engineer whose mass is 70kgholds onto the outer rim of a rotating space station whose radius is 14mand which takes 30sto make one complete rotation. What is the magnitude of the force the engineer has to exert in order to hold on? What is the magnitude of the net force acting on the engineer?

You're driving a vehicle of mass 1350kgand you need to make a turn on a flat road. The radius of curvature of the turn is. The coefficient of static friction and the coefficient of kinetic friction are both 0.25.

(a) What is the fastest speed you can drive and still make it around the turn? Invent symbols for the various quantities and solve algebraically before plugging in numbers.

(b) Which of the following statements are true about this situation?

(1) The net force is nonzero and points away from the centre of the kissing circle. (2) The rate of change of the momentum is nonzero and points away from the centre of the kissing circle.

(3) The rate of change of the momentum is nonzero and points toward the centre of the kissing circle.

(4) The momentum points toward the centre of the kissing circle.

(5) The centrifugal force balances the force of the road, so the net force is zero. (6) The net force is nonzero and points two and the centre of the kissing circle.

(c) Look at your algebraic analysis and answer the following question. Suppose that your vehicle had a mass five times as big(6750kg). Now what is the fastest speed you can drive and still make it around the turn?

(d) Look at your algebraic analysis and answer the following question. Suppose that you have the originalvehicle but the turn has a radius twice as large (152 m). What is the fastest speed you can drive and still make it around the turn? This problem shows why high-speed curves on freeways have very large radii of curvature, but low-speed entrance and exit ramps can have smaller radii of curvature.

You swing a bucket full of water in a vertical circle at the end of a rope. The mass of the bucket plus the water is 3.5kg. The center of mass of the bucket plus the water moves in a circle of radius 1.3m. At the instant that the bucket is at the top of the circle, the speed of the bucket is 4 m/s. What is the tension in the rope at this instant?

In outer space a rock of mass 4kgis attached to a long spring and swung at constant speed in a circle of radius 9m. The spring exerts a force of constant magnitude 760N.

(a) What is the speed of the rock?

(b) What is the direction of the spring force?

(c)The relaxed length of the spring is 8.7m. What is the stiffness of this spring?

An800kgload is suspended as shown in Figure 5.69. (a) Calculate the tension in all three wires (that is, the magnitude of the tension force exerted by each of these wires). (b) These wires are made of a material whose value for Young’s modulus is 1.3×1011N/m2. The diameter of the wires is 1.1m. What is the strain (fractional stretch) in each wire?
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