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Technological Impacts

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Statics Using 2 index cards: Create a structure or system of structures that will elevate two textbooks at least 1.5cm off your desk – PowerPoint PPT presentation

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Title: Technological Impacts


1
Statics
Using 2 index cards Create a structure or
system of structures that will elevate two
textbooks at least 1.5cm off your desk
2
Statics
What is Statics? Branch of Mechanics that
deals with objects/materials that are stationary
or in uniform motion. Forces are
balanced. Examples 1. A book lying on a table
(statics) 2. Water being held behind a dam
(hydrostatics)
Kentucky Indiana Bridge
Chicago
3
Dynamics
Dynamics is the branch of Mechanics that
deals with objects/materials that are
accelerating due to an imbalance of
forces. Examples 1. A rollercoaster executing
a loop (dynamics) 2. Flow of water from a hose
(hydrodynamics)
4
  • Total degrees in a triangle
  • Three angles of the triangle below
  • Three sides of the triangle below
  • Pythagorean Theorem
  • x2 y2 r2

180
A, B, and C
x, y, and r
B
r
y
HYPOTENUSE
A
C
x
5
Trigonometric functions are ratios of the
lengths of the segments that make up angles.
r
y
Q
x
6
For ltA below, calculate Sine, Cosine, and
Tangent
B
opposite adjacent
1 2
tan A
sin A
A
C
1 v3
tan A
v3 2
cos A
7
Law of Cosines c2 a2 b2 2ab cos C Law of
Sines sin A sin B sin C a
b c
B
c
a
C
A
b

8
  • Scalar a variable whose value is expressed only
    as a magnitude or quantity
  • Height, pressure, speed, density, etc.
  • Vector a variable whose value is expressed both
    as a magnitude and direction
  • Displacement, force, velocity, momentum, etc.
  • 3. Tensor a variable whose values are
    collections of vectors, such as stress on a
    material, the curvature of space-time (General
    Theory of Relativity), gyroscopic motion, etc.

9
  • Properties of Vectors
  • Magnitude
  • Length implies magnitude of vector
  • Direction
  • Arrow implies direction of vector
  • Act along the line of their direction
  • No fixed origin
  • Can be located anywhere in space

10
Bold type and an underline F also identify vectors
Vectors - Description
Magnitude, Direction
Hat signifies vector quantity
F 40 lbs 45o
F 40 lbs _at_ 45o
direction
magnitude
40 lbs
45o
11
Vectors Scalar Multiplication
  1. We can multiply any vector by a whole number.
  2. Original direction is maintained, new magnitude.

2
½
12
Vectors Addition
  1. We can add two or more vectors together.
  2. 2 methods
  3. Graphical Addition/subtraction redraw vectors
    head-to-tail, then draw the resultant vector.
    (head-to-tail order does not matter)

13
Vectors Rectangular Components
  1. It is often useful to break a vector into
    horizontal and vertical components (rectangular
    components).
  2. Consider the Force vector below.
  3. Plot this vector on x-y axis.
  4. Project the vector onto x and y axes.

y
F
Fy
x
Fx
14
Vectors Rectangular Components
This means vector F vector Fx
vector Fy Remember the addition of
vectors
y
F
Fy
x
Fx
15
Unit vector
Vectors Rectangular Components
Vector Fx Magnitude Fx times vector i
F Fx i Fy j
Fx Fx i
i denotes vector in x direction
y
Vector Fy Magnitude Fy times vector j
F
Fy Fy j
Fy
j denotes vector in y direction
x
Fx
16
Vectors Rectangular Components
Each grid space represents 1 lb force. What is
Fx? Fx (4 lbs)i What is Fy? Fy (3
lbs)j What is F? F (4 lbs)i (3 lbs)j
y
F
Fy
x
Fx
17
Vectors Rectangular Components
If vector V a i b j c k then
the magnitude of vector V V
18
Vectors Rectangular Components
What is the relationship between Q, sin Q, and
cos Q?
cos Q Fx / F Fx F cos Qi sin Q Fy /
F Fy F sin Qj
F
Fy
Q
Fx
19
Vectors Rectangular Components
When are Fx and Fy Positive/Negative?
Fy
Fy
y
F
Fx
Fx -
F
x
F
F
Fx -
Fx
Fy -
Fy -
20
Vectors Rectangular Components
Complete the following chart in your notebook
I
II
III IV
21
Vectors
  • Vectors can be completely represented in two
    ways
  • Graphically
  • Sum of vectors in any three independent
    directions
  • Vectors can also be added/subtracted in either of
    those ways
  • F1 ai bj ck F2 si tj uk
  • F1 F2 (a s)i (b t)j (c u)k

22
Vectors
A third way to add, subtract, and otherwise
decompose vectors Use the law of sines or
the law of cosines to find R.
R
45o
30o
F1
F2
105o
23
Vectors
  • Brief note about subtraction
  • If F ai bj ck, then F ai bj
    ck
  • Also, if
  • F
  • Then,
  • F

24
Resultant Forces
Resultant forces are the overall combination of
all forces acting on a body. 1) find sum
of forces in x-direction 2) find sum of forces
in y-direction 3) find sum of forces in
z-direction 3) Write as single vector in
rectangular components
R SFxi SFyj SFzk
25
Resultant Forces - Example
  • A satellite flies without friction in space.
    Earths gravity pulls downward on the satellite
    with a force of 200 N. Stray space junk hits the
    satellite with a force of 1000 N at 60o to the
    horizontal. What is the resultant force acting
    on the satellite?
  • Sketch and label free-body diagram (all external
    and reactive forces acting on the body)
  • Decompose all vectors into rectangular components
    (x, y, z)
  • Add vectors

26
Statics
Now on to the point
  • Newtons 3 Laws of Motion
  • A body at rest will stay at rest, a body in
    motion will stay in motion, unless acted upon by
    an external force
  • This is the condition for static equilibrium
  • In other wordsthe net force acting upon a body
    is
  • Zero

27
  • Newtons 3 Laws of Motion
  • Force is proportional to mass times acceleration
  • F ma
  • If in static equilibrium, the net force acting
    upon a body is
  • Zero
  • What does this tell us about the acceleration of
    the body?
  • It is Zero

28
  • Newtons 3 Laws of Motion
  • Action/Reaction

29
Statics
  • Two conditions for static equilibrium

Since Force is a vector, this implies
Individually.
30
Two conditions for static equilibrium 1.
31
Two conditions for static equilibrium Why isnt
sufficient?
32
  • Two conditions for static equilibrium
  • About any point on an object,
  • Moment M (or torque t) is a scalar quantity that
    describes the amount of twist at a point.
  • M (magnitude of force perpendicular to moment
    arm) (length of moment arm) (magnitude of
    force) (perpendicular distance from point to
    force)

33
  • Two conditions for static equilibrium
  • MP F x MP Fy x
  • M (magnitude of force perpendicular to moment
    arm) (length of moment arm) (magnitude of
    force) (perpendicular distance from point to
    force)

F
F
P
P
x
x
34
  • Moment Examples
  • Tension test apparatus unknown and reaction
    forces?
  • If a beam supported at its endpoints is given a
    load F at its midpoint, what are the supporting
    forces at the endpoints?
  • Find sum of moments about a or b.

Ra
Rb
Watch your signs identify positive
35
  • Moment Examples
  • An L lever is pinned at the center P and holds
    load F at the end of its shorter leg. What force
    is required at Q to hold the load? What is the
    force on the pin at P holding the lever?
  • What is your method for solving this problem?
    Remember,

36
Trusses
Trusses A practical and economic solution to
many structural engineering challenges Simple
truss consists of tension and compression
members held together by hinge or pin joints
Rigid truss will not collapse
37
Trusses
Joints Pin or Hinge (fixed)
38
Trusses
Supports Pin or Hinge (fixed) 2
unknowns
Reaction in x-direction Reaction in y-direction
Rax
Ray
39
Trusses
Supports Roller - 1 unknown
Reaction in y-direction only
Ray
40
  • Assumptions to analyze simple truss
  • Joints are assumed to be frictionless, so
    forces can only be transmitted in the direction
    of the members.
  • Members are assumed to be massless.
  • Loads can be applied only at joints (or
    nodes).
  • Members are assumed to be perfectly rigid.
  • 2 conditions for static equilibrium
  • Sum of forces at each joint (or node) 0
  • Moment about any joint (or node) 0
  • Start with Entire Truss Equilibrium Equations

41
Truss Analysis Example Problems 1. A force F is
applied to the following equilateral truss.
Determine the force in each member of the truss
shown and state which members are in compression
and which are in tension.
42
Truss Analysis Example Problems 2. Using the
method of joints, determine the force in each
member of the truss shown. Assume equilateral
triangles.
43
Static determinacy and stability Statically
Determinant All unknown reactions and forces
in members can be determined by the methods of
statics all equilibrium equations can be
satisfied. m 2j r (Simple
Truss) Static Stability The truss is rigid it
will not collapse.
44
Conditions of static determinacy and stability of
trusses
45
  • Materials Lab Connections
  • Tensile Strength Force / Area
  • Compression is Proportional to 1 / R4
  • Problem Sheet solutions due Monday
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