1. CHAPTER 8 TIME AND TIME-RELATED PARAMETERS

2. Introduction
Good engineers recognize the role of time in their lives and in calculating:
speed,
acceleration,
flow of traffic, and
flow of materials and substances.
They know what is meant by frequency and period of oscillation and understand the difference between a steady and a transient process.
In this chapter, we will investigate the role of time as a fundamental dimension and other time-related engineering parameters, such as frequency and period.

3. The following Table shows the relationship between the time and other fundamental dimensions.

4. Time as a Fundamental Dimension
We live in a dynamic world.
Everything in the universe is in a constant state of motion.
Time is an important parameter in describing motion.
Example: How long does it take to cover a certain distance?
We have also associated time with natural occurrences in our lives,
for example, to express the relative position of the earth with
respect to the sun, we use: day, night, 2:00 a.m., or May 30.
The parameter time has been divided into smaller and larger
intervals, such as seconds, minutes, hours, days, months, etc

5. Measurement of Time
Early humans relied on the relative position of the earth with respect to the sun, moon, stars, or other planets to keep track of time.
Sun clocks, known as shadow clocks or sundials, were used to divide a given day into smaller periods.
But, human needed to devise a means to keep track of shorter time intervals. This need led to the development of clocks.
During the 16th century, came spring-loaded clocks. The spring mechanism design eventually led to smaller clocks and to watches.
Quartz clocks eventually replaced the mechanical clocks around the middle of the 20th century.

6. The Need for Time Zones
The earth rotates about an axis that runs from the South Pole to the North Pole, and it takes the earth 24 hours to complete one revolution about this axis (see next slide).
The earth is divided into 360 circular arcs that are equally spaced from east to west; these arcs are called longitudes. The zero longitude was arbitrarily assigned to the arc that passes through Greenwich, England.
Because it takes the earth 24 hours to complete one revolution about its axis, every 15 degrees longitude corresponds to 1 hour (360 degrees/24 hours ).
The earth is also divided into latitudes, which measure the angle formed by the line connecting the center of the earth to the specific location on the surface of the earth and the equatorial plane, see next slide. The latitude varies from 0 degrees to 90 degrees north (North Pole) and from 0 degrees to 90 degrees south
The need for time zones was not realized until the latter part of the 19th century. The standard time zones are shown in Figure 8.3 (see next slide).

9. Periods and Frequencies
For periodic events, a period is the time that it takes for the event to repeat itself. For example, every 365 days the earth lines up in exactly the same position with respect to the sun. The orbit of the earth around the sun is said to be periodic because this event repeats itself.
The inverse of a period is called a frequency f=1/T. For example, the frequency at which the earth goes around the sun is once a year.

10. Example
Solution

11. Vehicle per hour
Vehicle per kilometer

12. Kilometer per hour
Example

13. Engineering Parameters Involving Length and Time
In this section, we will consider derived physical quantities that are based on the fundamental dimensions of length and time such as the concepts of linear speed, acceleration and volumetric flow rate.
1- Linear Velocities
Knowledge of linear speed and acceleration is important to engineers when designing:
conveyer belts, automatic walkways, escalators, water or gas flow inside pipes
as civil engineers, concerned with velocities, particularly, when designing
structures, they need to account for the wind speed and its direction
the average speed, which is defined as:

14. 2- Linear Accelerations
Acceleration provides a measure of how velocity changes
with time.
Something that moves with a constant velocity has a zero
acceleration.
Because velocity is a vector quantity and has both magnitude and direction, any change in either the direction or the magnitude of velocity can create acceleration. The average acceleration is defined as
Therefore, acceleration is the time rate of change of velocity.
The SI unit for acceleration is m/s2 and in U.S. Customary units ft /s2.

15. At the surface of the earth, the attractive force F is called the weight of an object,
and the acceleration created by the force is referred to as the acceleration due to gravity (g). The value of g is equal to 9.81 m/s2, or 32.2 ft/s2.
Force= mass x acceleration
Table 8.3 shows speed, acceleration, and the distance traveled by a falling object from the roof of a high-rise building. Note how the distance traveled by the falling object and its velocity change with time. As v=gt

16. Example

18. Volumetric Flow Rate
Engineers design flow-measuring devices to determine the amount of a material or
a substance flowing through a pipeline in a processing plant.
Volumetric flow rate measurements are necessary in many industrial processes to
keep track of the amount of material being transported from one point to the next point in a plant.

19. Example