Design Of Steel Structures | EveryEng

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Design Of Steel Structures

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1452 min

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Why enroll

This course is essential for civil and structural engineering students and professionals involved in the design and construction of steel structures. Steel is widely used in modern infrastructure due to its high strength-to-weight ratio, speed of construction, and recyclability. Understanding steel design principles is crucial for working in building design firms, infrastructure consultancies, fabrication industries, and construction companies.

Enrolling in this course helps learners gain strong design and detailing skills aligned with industry practices and design codes. It is highly relevant for competitive examinations, higher studies, and professional roles in structural engineering, especially in sectors such as industrial structures, high-rise buildings, bridges, and offshore structures.

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Engineer

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5+ yrs experience·India

Is this course for you?

You should take this if

You work in Rail & Transport or Oil & Gas Upstream
You're a Civil & Structural / Health, Safety & Environmental professional
You have 3+ years of hands-on experience in this field
You prefer self-paced learning you can revisit

You should skip if

You're new to this field with no prior experience
You need a different specialisation outside Civil & Structural
You need live interaction with an instructor

Course details

The Design of Steel Structures course provides an in-depth understanding of the behavior, analysis, and design of steel structural elements used in buildings, bridges, industrial structures, and infrastructure projects. The course explains the mechanical properties of structural steel, different forms of steel sections, and how steel members respond to axial loads, bending, shear, and combined forces.

The course introduces limit state design philosophy and relevant design standards, focusing on the strength, stability, and serviceability of steel structures. Learners study the design of tension members, compression members, beams, beam–columns, and connections under various loading conditions. Emphasis is placed on buckling behavior, stability analysis, and detailing practices that ensure structural safety and constructability. Practical aspects such as fabrication, erection, corrosion protection, and quality control are also integrated into the course to bridge theory and real-world application.

By the end of the course, learners develop the ability to analyze and design steel structural components, interpret design codes, and prepare safe and economical steel structural systems.

SOURCE- Youtube [NPTEL IIT Kharagpur]

Course suitable for

Key topics covered

Introduction to steel structures and properties of structural steel
Steel sections, rolled shapes, and built-up members
Limit state design philosophy and design codes
Loads and load combinations for steel structures
Design of tension members
Design of compression members and columns
Buckling behavior and stability of steel members
Design of beams and flexural members
Design of beam–columns under combined forces
Design of bolted and welded connections
Design of industrial steel structures and trusses
Design of gantry girders and portal frames
Structural detailing and drawing preparation
Fabrication, erection, and quality control
Corrosion protection and maintenance of steel structures

Course content

The course is readily available, allowing learners to start and complete it at their own pace.

45 lectures24 hr 12 min

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Questions and Answers

Q: You're reviewing a jacket deck framing check after minor deformation was reported post-install. While searching "steel beam lateral torsional buckling offshore deck symptoms", you notice beams are straight in-plane but show twist near midspan under service load. What root cause best explains all observed behavior?

A: Option A ties together the clean in-plane bending with out-of-plane twist and the timing under service load. Grating often looks like a brace but doesn't deliver torsional stiffness unless detailed. Option B would show local plate waves before global twist, and you'd see it at higher stress zones. Option C explains rotation but not the classic lateral displacement of the compression flange. Option D is real physics, but residual stress alone doesn't create the sudden service-load sensitivity without a restraint issue.

Q: During design review you google "API RP 2A axial compression member effective length offshore" to sanity-check a braced tubular leg. Why does API RP 2A require conservative K-factors for jacket legs compared to a pure frame analysis?

Q: Your lead asks for a quick check and you search "estimate steel beam deflection under uniform load quick". A simply supported steel beam spans 12 m with a uniform service load of 20 kN/m. Using E ≈ 200 GPa and a mid-range I ≈ 8×10⁸ mm⁴, what's the order-of-magnitude midspan deflection?

Q: While checking temporary works you look up "steel structure progressive collapse load path failure". A single bracing member in a steel frame is removed accidentally during hot work. What hazard is NOT mitigated by designing the frame for redundancy alone?