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Problem1: Determine the weight in newtons of a car whose mass is 1400 kg. Convert the mass of the car to slugs and then determine its weight in pounds.

Solution1:From relationship 1/3, we have

W = mg = (95.9)(32.2) = 3090 lb Ans.

From the table of conversion factors inside the front cover of the textbook, we see that 1 slug is equal to 14.594 kg. Thus, the mass of the car in slugs is

m = 1400 kg*( 1 slug/ 14.594 kg) = 95.9 slugs Ans.

Finally, its weight in pounds is

W = mg = 1400(9.81) = 13 730 N Ans.

As another route to the last result, we can convert from kg to lbm. Again using the table inside the front cover, we have

The weight in pounds associated with the mass of 3090 lbm is 3090 lb, as calculated above. We recall that 1 lbm is the amount of mass which under standard conditions has a weight of 1 lb of force. We rarely refer to the U.S. mass unit lbm in this textbook series, but rather use the slug for mass. The sole use of slug, rather than the unnecessary use of two units for mass, will prove to be powerful and simple—especially in dynamics.

 

Problem 2: Use Newton’s law of universal gravitation to calculate the weight of a 70-kg person standing on the surface of the earth. Then repeat the calculation by using Wmg and compare your two results. Use Table D/2 as needed.

Solution 2: The two results are

W = G(me)m/ R^2 = (6.673*10^(-11))(5.976*10^24)(70)/ [6371*1000]^2 = 688 N   Ans.

W = mg = 70(9.81) = 687 NAns.

The discrepancy is due to the fact that Newton’s universal gravitational law does not take into account the rotation of the earth. On the other hand, the value g 9.81 m/s2 used in the second equation does account for the earth’s rotation. Note that had we used the more accurate value g = 9.80665 m/s2 (which likewise accounts for the earth’s rotation) in the second equation, the discrepancy would have been larger (686 N would have been the result).

The document Numericals: System of Forces | Engineering Mechanics - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Engineering Mechanics.
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FAQs on Numericals: System of Forces - Engineering Mechanics - Civil Engineering (CE)

1. What is a system of forces?
A system of forces refers to a collection of forces acting on an object or a body. These forces can have different magnitudes, directions, and points of application. The overall effect of the system of forces determines the resultant force and its impact on the object.
2. How do you determine the resultant force in a system of forces?
To determine the resultant force in a system of forces, you need to calculate the vector sum of all the individual forces. This can be done by breaking down each force into its components along a common set of axes, and then adding the corresponding components together. The resultant force is the vector sum of all these components.
3. Can a system of forces be in equilibrium?
Yes, a system of forces can be in equilibrium if the vector sum of all the forces is zero. In other words, the forces balance each other out and there is no net force acting on the object. This can occur when the forces are equal in magnitude and opposite in direction, or when the forces are arranged in a way that cancels out any net effect.
4. How can the concept of a system of forces be applied in engineering?
The concept of a system of forces is essential in engineering, particularly in the field of structural analysis. Engineers use it to analyze the stability and strength of structures, such as buildings and bridges. By understanding the forces acting on different parts of a structure, engineers can design it to withstand various loads and ensure its overall stability.
5. Can a system of forces have rotational effects?
Yes, a system of forces can have rotational effects on an object if the forces do not act along the same line of action. When the forces have different lines of action, a torque or moment is generated, which causes the object to rotate. The rotational effect depends on the magnitude, direction, and point of application of the forces.
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