Ch 08: Dynamics II: Motion in a Plane

Knight Calc - Physics for Scientists and Engineers 5th Edition

Knight Calc5th EditionPhysics for Scientists and EngineersISBN: 9780137344796Not the one you use?Change textbook

Knight Calc 5th Edition

Ch 08: Dynamics II: Motion in a Plane

Problem 30b

Chapter 8, Problem 30b

An 85,000 kg stunt plane performs a loop-the-loop, flying in a 260-m-diameter vertical circle. At the point where the plane is flying straight down, its speed is 55 m/s and it is speeding up at a rate of 12 m/s per second. What angle does the net force make with the horizontal? Let an angle above horizontal be positive and an angle below horizontal be negative.

Verified step by step guidance

Step 1: Identify the forces acting on the stunt plane at the point where it is flying straight down. These forces include the gravitational force (weight), the normal force from the circular motion, and the net force due to acceleration.

Step 2: Calculate the gravitational force acting on the plane using the formula:

F = m g

, where

m

is the mass of the plane (85,000 kg) and

g

is the acceleration due to gravity (9.8 m/s²).

Step 3: Determine the centripetal force required for circular motion using the formula:

F = \frac{m v^{2}}{r}

, where

v

is the speed of the plane (55 m/s) and

r

is the radius of the circle (half the diameter, 130 m).

Step 4: Calculate the net force acting on the plane using the formula:

F = m a

, where

a

is the acceleration (12 m/s²). Combine this with the forces calculated in Steps 2 and 3 to find the total net force vector.

Step 5: Use trigonometry to find the angle of the net force with respect to the horizontal. The vertical component of the net force is the sum of the gravitational force and the centripetal force, while the horizontal component is due to the acceleration. Use the formula:

θ = \tan (F

_verticalF_horizontal) to calculate the angle, ensuring the sign convention for above or below the horizontal is applied.

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above.

Video duration:

Was this helpful?

Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Net Force

Net force is the vector sum of all forces acting on an object. In the context of the stunt plane, it includes gravitational force and the aerodynamic forces acting on the plane. Understanding net force is crucial for determining the resultant direction and magnitude of the forces, which directly affects the plane's motion during the loop.

Centripetal Acceleration

Centripetal acceleration is the acceleration directed towards the center of a circular path, necessary for an object to maintain circular motion. For the stunt plane, this acceleration is influenced by its speed and the radius of the loop. It plays a key role in calculating the net force acting on the plane at different points in the loop, particularly when it is at the bottom of the loop.

Angle of Net Force

The angle of the net force with respect to the horizontal indicates the direction of the resultant force acting on the plane. This angle can be determined using trigonometric relationships based on the components of the net force, which include both vertical and horizontal forces. Understanding this angle is essential for analyzing the plane's dynamics and ensuring it performs the loop safely.

Recommended video:

Guided course

06:28

Finding Net Forces in 2D Gravitation

Related Practice

Textbook Question

A toy train rolls around a horizontal 1.0-m-diameter track. The coefficient of rolling friction is 0.10. How long does it take the train to stop if it's released with an angular speed of 30 rpm?

2364

views

Textbook Question

You are driving your 1800 kg car at 25 m/s over a circular hill that has a radius of 150 m. A deer running across the road causes you to hit the brakes hard while right at the summit of the hill, and you start to skid. The coefficient of kinetic friction between your tires and the road is 0.75. What is the magnitude of your acceleration as you begin to slow?

3241

views

Textbook Question

CALC A 100 g bead slides along a frictionless wire with the parabolic shape y = (2m^-1) x². Find an expression for a_y, the vertical component of acceleration, in terms of x, v_x, and a_x. Hint: Use the basic definitions of velocity and acceleration.

2294

views

Textbook Question

A new car is tested on a 200-m-diameter track. If the car speeds up at a steady 1.5 m/s², how long after starting is the magnitude of its centripetal acceleration equal to the tangential acceleration?

2507

views

Textbook Question

A 250 g ball is launched with a speed of 35 m/s at a 30° angle. A strong headwind exerts a constant horizontal drag force on the ball. What is the magnitude of the drag force if the wind reduces the ball's travel distance by 20%?

1760

views

Textbook Question

A motorcycle daredevil plans to ride up a 2.0-m-high, 20° ramp, sail across a 10-m-wide pool filled with hungry crocodiles, and land at ground level on the other side. He has done this stunt many times and approaches it with confidence. Unfortunately, the motorcycle engine dies just as he starts up the ramp. He is going 11 m/s at that instant, and the rolling friction of his rubber tires (coefficient 0.02) is not negligible. Does he survive, or does he become crocodile food? Justify your answer by calculating the distance he travels through the air after leaving the end of the ramp.

1373

views