Engineering Mechanics: Statics

Engineering Mechanics: Statics

Chapter 1General Principles

Chapter 1General Principles

Chapter ObjectivesChapter Objectives

To provide an introduction to the basic quantities and idealizations of mechanics.

To give a statement of Newton’s Laws of Motion and Gravitation.

To review the principles for applying the SI system of units.

To examine the standard procedures for performing numerical calculations.

To present a general guide for solving problems.

Chapter OutlineChapter Outline

MechanicsFundamental ConceptsUnits of MeasurementThe International System of UnitsNumerical CalculationsGeneral Procedure for Analysis

1.1 Mechanics1.1 Mechanics

Mechanics can be divided into 3 branches:- Rigid-body Mechanics- Deformable-body Mechanics- Fluid Mechanics

Rigid-body Mechanics deals with - Statics - Dynamics

1.1 Mechanics1.1 Mechanics

Statics – Equilibrium of bodies At rest Move with constant velocity

Dynamics – Accelerated motion of bodies

1.2 Fundamentals Concepts 1.2 Fundamentals Concepts

Basic Quantities Length

– Locate position and describe size of physical system– Define distance and geometric properties of a body

Mass – Comparison of action of one body against another– Measure of resistance of matter to a change in velocity

1.2 Fundamentals Concepts 1.2 Fundamentals Concepts

Basic Quantities Time

– Conceive as succession of events Force

– “push” or “pull” exerted by one body on another– Occur due to direct contact between bodies Eg: Person pushing against the wall– Occur through a distance without direct contact Eg: Gravitational, electrical and magnetic forces

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Idealizations Particles

– Consider mass but neglect sizeEg: Size of Earth insignificant compared to its size of orbit

Rigid Body– Combination of large number of particles – Neglect material propertiesEg: Deformations in structures, machines and mechanism

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Idealizations Concentrated Force

– Effect of loading, assumed to act at a point on a body

– Represented by a concentrated force, provided loading area is small compared to overall sizeEg: Contact force between wheel and ground

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Newton’s Three Laws of Motion First Law

“A particle originally at rest, or moving in a straight line with constant velocity, will remain in this state provided that the particle is not subjected to an unbalanced force”

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Newton’s Three Laws of Motion Second Law

“A particle acted upon by an unbalanced force F experiences an acceleration a that has the same direction as the force and a magnitude that is directly proportional to the force” maF

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Newton’s Three Laws of Motion Third Law

“The mutual forces of action and reaction between two particles are equal and, opposite and collinear”

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Newton’s Law of Gravitational Attraction

F = force of gravitation between two particlesG = universal constant of gravitationm1,m2 = mass of each of the two particlesr = distance between the two particles

221

r

mmGF

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Weight,

Letting yields

2r

mMGW e

2/ rGMg e

mgW

1.2 Fundamentals Concepts1.2 Fundamentals Concepts

Comparing F = mg with F = ma g is the acceleration due to gravity Since g is dependent on r, weight of a body

is not an absolute quantity Magnitude is determined from where the

measurement is taken For most engineering calculations, g is

determined at sea level and at a latitude of 45°

1.3 Units of Measurement1.3 Units of Measurement

SI Units Système International d’UnitésF = ma is maintained only if

– Three of the units, called base units, are arbitrarily defined – Fourth unit is derived from the equation

SI system specifies length in meters (m), time in seconds (s) and mass in kilograms (kg)

Unit of force, called Newton (N) is derived from F = ma

1.3 Units of Measurement1.3 Units of Measurement

2.

s

mkg

Name Length Time Mass Force

International Systems of Units (SI)

Meter (m)

Second (s)

Kilogram (kg)

Newton (N)

1.3 Units of Measurement1.3 Units of Measurement

At the standard location, g = 9.806 65 m/s2

For calculations, we use g = 9.81 m/s2

Thus,

W = mg (g = 9.81m/s2)Hence, a body of mass 1 kg has a

weight of 9.81 N, a 2 kg body weighs 19.62 N

1.4 The International System of Units

1.4 The International System of Units

PrefixesFor a very large or very small numerical

quantity, the units can be modified by using a prefix

Each represent a multiple or sub-multiple of a unitEg: 4,000,000 N = 4000 kN (kilo-newton)

= 4 MN (mega- newton) 0.005m = 5 mm (milli-meter)

1.4 The International System of Units

1.4 The International System of Units

Exponential Form

Prefix SI Symbol

Multiple1 000 000 000 109 Giga G

1 000 000 106 Mega M

1 000 103 Kilo k

Sub-Multiple0.001 10-3 Milli m

0.000 001 10-6 Micro μ

0.000 000 001 10-9 nano n

1.4 The International System of Units

1.4 The International System of Units

Rules for UseNever write a symbol with a plural

“s”. Easily confused with second (s)

Symbols are always written in lowercase letters, except the 2 largest prefixes, mega (M) and giga (G)

Symbols named after an individual are capitalized Eg: newton (N)

1.4 The International System of Units

1.4 The International System of Units

Rules for UseQuantities defined by several units

which are multiples, are separated by a dotEg: N = kg.m/s2 = kg.m.s-2

The exponential power represented for a unit having a prefix refer to both the unit and its prefixEg: μN2 = (μN)2 = μN. μN

1.4 The International System of Units

1.4 The International System of Units

Rules for UsePhysical constants with several digits

on either side should be written with a space between 3 digits rather than a commaEg: 73 569.213 427

In calculations, represent numbers in terms of their base or derived units by converting all prefixes to powers of 10

1.4 The International System of Units

1.4 The International System of Units

Rules for UseEg: (50kN)(60nm) = [50(103)N][60(10-

9)m] = 3000(10-6)N.m = 3(10-3)N.m = 3 mN.m

The final result should be expressed using a single prefix

1.4 The International System of Units

1.4 The International System of Units

Rules for Use Compound prefix should not be used

Eg: kμs (kilo-micro-second) should be expressed as ms (milli-second) since

1 kμs = 1 (103)(10-6) s = 1 (10-3) s = 1ms With exception of base unit kilogram, avoid

use of prefix in the denominator of composite unitsEg: Do not write N/mm but rather kN/mAlso, m/mg should be expressed as Mm/kg

1.4 The International System of Units

1.4 The International System of Units

Rules for UseAlthough not expressed in terms of

multiples of 10, the minute, hour etc are retained for practical purposes as multiples of second.

Plane angular measurements are made using radians. In this class, degrees would be often used where 180° = π rad

1.5 Numerical Calculations1.5 Numerical Calculations

Dimensional Homogeneity- Each term must be expressed in the same unitsEg: s = vt + ½ at2 where s is position in meters (m), t is time in seconds (s), v is velocity in m/s and a is acceleration in m/s2

- Regardless of how the equation is evaluated, it maintains its dimensional homogeneity

1.5 Numerical Calculations1.5 Numerical Calculations

Dimensional Homogeneity- All the terms of an equation can be replaced by a consistent set of units, that can be used as a partial check for algebraic manipulations of an equation

1.5 Numerical Calculations1.5 Numerical Calculations

Significant Figures- The accuracy of a number is specified by the number of significant figures it contains

- A significant figure is any digit including zero, provided it is not used to specify the location of the decimal point for the numberEg: 5604 and 34.52 have four significant numbers

1.5 Numerical Calculations1.5 Numerical Calculations

Significant Figures- When numbers begin or end with zero, we make use of prefixes to clarify the number of significant figures

Eg: 400 as one significant figure would be 0.4(103) 2500 as three significant figures would be 2.50(103)

1.5 Numerical Calculations1.5 Numerical Calculations

Computers are often used in engineering foradvanced design and analysis

1.5 Numerical Calculations1.5 Numerical Calculations

Rounding Off Numbers- For numerical calculations, the accuracy obtained from the solution of a problem would never be better than the accuracy of the problem data

- Often handheld calculators or computers involve more figures in the answer than the number of significant figures in the data

1.5 Numerical Calculations1.5 Numerical Calculations

Rounding Off Numbers- Calculated results should always be “rounded off” to an appropriate number of significant figures

1.5 Numerical Calculations1.5 Numerical Calculations

Rules for Rounding to n significant figures- If the n+1 digit is less than 5, the n+1 digit and others following it are droppedEg: 2.326 and 0.451 rounded off to n = 2 significance figures would be 2.3 and 0.45

- If the n+1 digit is equal to 5 with zero following it, then round nth digit to an even numberEg: 1.245(103) and 0.8655 rounded off to n = 3 significant figures become 1.24(103) and 0.866

1.5 Numerical Calculations1.5 Numerical Calculations

Rules for Rounding to n significant figures- If the n+1 digit is greater than 5 or equal to 5 with non-zero digits following it, increase the nth digit by 1 and drop the n+1digit and the others following itEg: 0.723 87 and 565.5003 rounded off to n = 3 significance figures become 0.724 and 566

1.5 Numerical Calculations1.5 Numerical Calculations

Calculations- To ensure the accuracy of the final results, always retain a greater number of digits than the problem data- If possible, try work out computations so that numbers that are approximately equal are not subtracted-In engineering, we generally round off final answers to three significant figures

1.5 Numerical Calculations1.5 Numerical Calculations

Example 1.1 Evaluate each of the following and express

with SI units having an approximate prefix: (a) (50 mN)(6 GN), (b) (400 mm)(0.6 MN)2, (c) 45 MN3/900 Gg

Solution First convert to base units, perform indicated operations and choose an appropriate prefix

1.5 Numerical Calculations1.5 Numerical Calculations

(a)

2

3326

26

93

300

10

1

10

110300

10300

1061050

650

kN

N

kN

N

kNN

N

NN

GNmN

1.5 Numerical Calculations1.5 Numerical Calculations

(b)

2

29

2123

263

2

.144

.10144

1036.010400

106.010400

6.0400

kNGm

Nm

Nm

Nm

MNmm

1.5 Numerical Calculations1.5 Numerical Calculations

kgkN

kgkN

kgN

kNN

kgN

kg

N

GgMN

/50

/1005.0

1

10

11005.0

/1005.0

10900

1045

900/45

3

33

3312

312

6

36

3

(c)

1.6 General Procedure for Analysis

1.6 General Procedure for Analysis

Most efficient way of learning is to solve problems

To be successful at this, it is important to present work in a logical and orderly way as suggested:1) Read problem carefully and try correlate actual physical situation with theory2) Draw any necessary diagrams and tabulate the problem data

1.6 General Procedure for Analysis

1.6 General Procedure for Analysis

3) Apply relevant principles, generally in mathematics forms4) Solve the necessary equations algebraically as far as practical, making sure that they are dimensionally homogenous, using a consistent set of units and complete the solution numerically5) Report the answer with no more significance figures than accuracy of the given data

1.6 General Procedure for Analysis

1.6 General Procedure for Analysis

6) Study the answer with technical judgment and common sense to determine whether or not it seems reasonable

1.6 General Procedure for Analysis

1.6 General Procedure for Analysis

When solving the problems, do the work as neatly as possible. Being neat generally stimulates clear and orderly thinking and vice versa.