ASVAB Mechanical Comprehension Practice Test 236275 Results

Your Results Global Average
Questions 5 5
Correct 0 3.38
Score 0% 68%

Review

1

Which of the following surfaces would have the highest coefficient of friction?

77% Answer Correctly

concrete

steel

ice

marble


Solution

Coefficient of friction (μ) represents how much two materials resist sliding across each other.  Smooth surfaces like ice have low coefficients of friction while rough surfaces like concrete have high μ.


2

Which of these is the formula for kinetic energy?

67% Answer Correctly

\(KE = {m \over v^2 }\)

\(KE = mgh\)

\(KE = {1 \over 2}mh^2\)

\(KE = {1 \over 2}mv^2\)


Solution

Kinetic energy is the energy of movement and is a function of the mass of an object and its speed: \(KE = {1 \over 2}mv^2\) where m is mass in kilograms, v is speed in meters per second, and KE is in joules. The most impactful quantity to kinetic energy is velocity as an increase in mass increases KE linearly while an increase in speed increases KE exponentially.


3

The science that deals with motion and the forces that produce motion is called which of the following?

57% Answer Correctly

aeronautics

physics

mechanics

engineering


Solution

Mechanics deals with motion and the forces that produce motion.


4

What is the first step to solving a problem where multiple forces are acting on an object?

61% Answer Correctly

calculate the total force

calculate kinetic energy

calculate potential energy

calculate the net force


Solution

In mechanics, multiple forces are often acting on a particular object and, taken together, produce the net force acting on that object. Like force, net force is a vector quantity in that it has magnitude and direction.


5

When all forces acting on a system cancel each other out, this is called:

80% Answer Correctly

equilibrium

stasis

rest

potential energy


Solution

When a system is stable or balanced (equilibrium) all forces acting on the system cancel each other out. In the case of torque, equilibrium means that the sum of the anticlockwise moments about a center of rotation equal the sum of the clockwise moments.