Introduction to Steel Design Principles
Introduction to Steel Design
Advantages of Steel as a Structural Material
Steel's high strength-to-weight ratio is crucial for long-span bridges and tall buildings.
Steel properties remain stable over time, unlike reinforced concrete.
Steel follows Hooke's law up to high stresses, allowing for accurate calculations.
Properly maintained steel frames can last indefinitely.
Ductility in structural steels prevents premature failures.
Steel's toughness enables it to absorb large amounts of energy.
Disadvantages of Steel as a Structural Material
Steel is susceptible to corrosion and requires periodic painting.
Strength of steel reduces significantly at high temperatures during fires.
Increased length and slenderness of compression members can lead to buckling.
Fatigue can reduce steel strength under repeated stress.
Steel may experience brittle fracture under certain conditions.
Additional Properties of Structural Steel
Tensile tests reveal key characteristics of steel for structural engineers.
Stress-strain relationship is linear up to the proportional limit.
Steel exhibits strain hardening and reaches a maximum stress value before fracture.
Elastic limit lies between the proportional limit and upper yield point.
Ultimate tensile strength is the maximum stress a material can withstand.
Modulus of elasticity (E) is the stress-strain ratio within the elastic range.
Types of Structural Steels
Plain carbon steels contain mostly iron and less than 1% carbon.
, Low-alloy steels include additional components for increased strength at the expense of
ductility.
High-alloy or specialty steels have higher strength and special qualities like corrosion resistance.
Structural Shapes and Sections
Hot-rolled Shapes:
Manufactured in a continuous casting system and shaped by rollers.
W-shape: Wide-flange shape with two parallel flanges, a single web, and two axes of symmetry.
Example: W18x50 indicates a wide-flange shape with a nominal depth of 18 inches and a weight
of 50 pounds per foot.
Common Steel Shapes
American Standard Shapes
S-shape: Similar to W-shape but with sloping flanges
W-shape: Two parallel flanges, a single web, and wider flanges compared to S-shape
I-beam: Former name for S-shape
Example: S18x70 indicates shape type, depth, and weight
Angle Shapes
Available in equal-leg or unequal-leg configurations
Designated by 'L' with lengths of legs and thickness
Weight per foot not provided
American Standard Channel
C-shape: Two flanges, a web, and sloping flanges
Designated by depth and weight per linear foot
Depth is exact, not nominal
Structural Tee
Produced by splitting an I-shaped member
Prefixes WT, ST, or MT depending on parent shape
Introduction to Steel Design
Advantages of Steel as a Structural Material
Steel's high strength-to-weight ratio is crucial for long-span bridges and tall buildings.
Steel properties remain stable over time, unlike reinforced concrete.
Steel follows Hooke's law up to high stresses, allowing for accurate calculations.
Properly maintained steel frames can last indefinitely.
Ductility in structural steels prevents premature failures.
Steel's toughness enables it to absorb large amounts of energy.
Disadvantages of Steel as a Structural Material
Steel is susceptible to corrosion and requires periodic painting.
Strength of steel reduces significantly at high temperatures during fires.
Increased length and slenderness of compression members can lead to buckling.
Fatigue can reduce steel strength under repeated stress.
Steel may experience brittle fracture under certain conditions.
Additional Properties of Structural Steel
Tensile tests reveal key characteristics of steel for structural engineers.
Stress-strain relationship is linear up to the proportional limit.
Steel exhibits strain hardening and reaches a maximum stress value before fracture.
Elastic limit lies between the proportional limit and upper yield point.
Ultimate tensile strength is the maximum stress a material can withstand.
Modulus of elasticity (E) is the stress-strain ratio within the elastic range.
Types of Structural Steels
Plain carbon steels contain mostly iron and less than 1% carbon.
, Low-alloy steels include additional components for increased strength at the expense of
ductility.
High-alloy or specialty steels have higher strength and special qualities like corrosion resistance.
Structural Shapes and Sections
Hot-rolled Shapes:
Manufactured in a continuous casting system and shaped by rollers.
W-shape: Wide-flange shape with two parallel flanges, a single web, and two axes of symmetry.
Example: W18x50 indicates a wide-flange shape with a nominal depth of 18 inches and a weight
of 50 pounds per foot.
Common Steel Shapes
American Standard Shapes
S-shape: Similar to W-shape but with sloping flanges
W-shape: Two parallel flanges, a single web, and wider flanges compared to S-shape
I-beam: Former name for S-shape
Example: S18x70 indicates shape type, depth, and weight
Angle Shapes
Available in equal-leg or unequal-leg configurations
Designated by 'L' with lengths of legs and thickness
Weight per foot not provided
American Standard Channel
C-shape: Two flanges, a web, and sloping flanges
Designated by depth and weight per linear foot
Depth is exact, not nominal
Structural Tee
Produced by splitting an I-shaped member
Prefixes WT, ST, or MT depending on parent shape
