FormulaDen.com
Physics
Chemistry
Math
Chemical Engineering
Civil
Electrical
Electronics
Electronics and Instrumentation
Materials Science
Mechanical
Production Engineering
Financial
Health
You are here
-
Home
»
Engineering
»
Civil
»
Bridge and Suspension Cable
Yield Strength of Steel in Bridge and Suspension Cable Formulas
Yield strength of steel is the level of stress that corresponds to the yield point. And is denoted by f
y
. Yield Strength of Steel is usually measured using the Megapascal for Stress. Note that the value of Yield Strength of Steel is always positive.
Formulas to find Yield Strength of Steel in Bridge and Suspension Cable
f
x
Reinforcing Steel Yield Strength given Force in Slab at Maximum Negative Moments
Go
f
x
Steel Yield Strength given Total Area of Steel Section
Go
f
x
Steel Yield Strength for Braced Non-Compact Section for LFD given Maximum Unbraced Length
Go
f
x
Steel Yield Strength for Compact Section for LFD given Minimum Flange Thickness
Go
f
x
Steel Yield Strength on Pins for Buildings for LFD given Allowable Bearing Stress
Go
f
x
Steel Yield Strength on Pins subject to Rotation for Bridges for LFD given Pin Stress
Go
f
x
Steel Yield Strength on Pins not Subject to Rotation for Bridges for LFD given Pin Stress
Go
f
x
Steel Yield Strength given Q Factor
Go
f
x
Steel Yield Strength given Buckling Stress for Q Factor Less than or Equal to 1
Go
f
x
Steel Yield Strength given Buckling Stress for Q Factor Greater than 1
Go
f
x
Steel Yield Strength given Allowable Unit Stress in Bending
Go
f
x
Steel Yield Strength using Allowable Shear Stress for Flexural Members in Bridges
Go
Bridge and Suspension Cable formulas that make use of Yield Strength of Steel
f
x
Area of Longitudinal Reinforcing given Force in Slab at Maximum Negative Moments
Go
f
x
Force in Slab at Maximum Negative Moments given Reinforcing Steel Yield Strength
Go
f
x
Force in Slab given Total Area of Steel Section
Go
f
x
Total Area of Steel Section given Force in Slab
Go
f
x
Shear Capacity for Flexural Members
Go
f
x
Shear Capacity for Girders with Transverse Stiffeners
Go
f
x
Allowable Stress for Compression Elements for Highway Bridges
Go
f
x
Maximum Bending Strength for Symmetrical Flexural Compact Section for LFD of Bridges
Go
f
x
Maximum Bending Strength for Symmetrical Flexural Braced Non-Compacted Section for LFD of Bridges
Go
f
x
Minimum Flange Thickness for Symmetrical Flexural Compact Section for LFD of Bridges
Go
f
x
Minimum Flange Thickness for Symmetrical Flexural Braced Non-Compact Section for LFD of Bridges
Go
f
x
Allowable Bearing Stresses on Pins for Buildings for LFD
Go
f
x
Allowable Bearing Stresses on Pins Subject to Rotation for Bridges for LFD
Go
f
x
Allowable Bearing Stresses on Pins not Subject to Rotation for Bridges for LFD
Go
f
x
Minimum Web Thickness for Symmetrical Flexural Compact Section for LFD of Bridges
Go
f
x
Maximum Unbraced Length for Symmetrical Flexural Compact Section for LFD of Bridges
Go
f
x
Maximum Unbraced Length for Symmetrical Flexural Braced Non-Compact Section for LFD of Bridges
Go
f
x
Area of Flange for Braced Non-Compact Section for LFD
Go
f
x
Depth of Section for Braced Non-Compact Section for LFD given Maximum Unbraced Length
Go
f
x
Width of Projection of Flange for Compact Section for LFD given Minimum Flange Thickness
Go
f
x
Q Factor
Go
f
x
Buckling Stress when Q Factor is Greater than 1
Go
f
x
Buckling Stress for Q Factor Less than or Equal to 1
Go
f
x
Allowable Unit Stress in Bending
Go
f
x
Allowable Stress when Slenderness Ratio is Less than Cc
Go
f
x
Allowable Shear Stress in Bridges
Go
f
x
Shear Buckling Coefficient given Allowable Shear Stress for Flexural Members in Bridges
Go
f
x
Allowable Stress for Expansion Rollers and Rockers where Diameter is up to 635 mm
Go
f
x
Allowable Stress for Expansion Rollers and Rockers where Diameter is from 635 mm to 3175 mm
Go
f
x
Diameter of Roller or Rocker for d up to 635 mm
Go
f
x
Diameter of Roller or Rocker for d from 635 to 3125mm
Go
List of variables in Bridge and Suspension Cable formulas
f
x
Slab Force
Go
f
x
Area of Steel Reinforcement
Go
f
x
Flange Area
Go
f
x
Maximum Unbraced Length
Go
f
x
Depth of Section
Go
f
x
Flange Minimum Thickness
Go
f
x
Width of Projection of Flange
Go
f
x
Allowable Bearing Stresses on Pins
Go
f
x
Factor Q
Go
f
x
Radius of Gyration
Go
f
x
Modulus of Elasticity
Go
f
x
Effective Length Factor
Go
f
x
Length of Member between Supports
Go
f
x
Buckling Stress
Go
f
x
Q Factors
Go
f
x
Allowable Unit Tensile Stress in bending
Go
f
x
Shear Stress for Flexural Members
Go
f
x
Shear Buckling Coefficient C
Go
FAQ
What is the Yield Strength of Steel?
Yield strength of steel is the level of stress that corresponds to the yield point. Yield Strength of Steel is usually measured using the Megapascal for Stress. Note that the value of Yield Strength of Steel is always positive.
Can the Yield Strength of Steel be negative?
No, the Yield Strength of Steel, measured in Stress cannot be negative.
What unit is used to measure Yield Strength of Steel?
Yield Strength of Steel is usually measured using the Megapascal[MPa] for Stress. Pascal[MPa], Newton per Square Meter[MPa], Newton per Square Millimeter[MPa] are the few other units in which Yield Strength of Steel can be measured.
Let Others Know
✖
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!