Design Wind Loading on a Steel Frame Warehouse

In this course, I will explain the full and detailed process of calculating the design wind pressures for structural members and cladding surfaces of the walls and roof of a steel-framed warehouse.

The assessment of wind loads for the design of structures is based on Australia/New Zealand standard AS1170.2 however the general concept remains the same for every other code.

AS1170 has a very detailed and comprehensive process for calculating wind pressures.

There are so many parameters and requirements in the code which often leaves people with some confusion and question marks on how to approach these. so I have decided to prepare this course to provide a clear roadmap for anyone who wants to learn the process step by step.

This course, “Design Wind Pressures on a Steel Structure Warehouse” includes two parts:

Please make sure to watch both parts to learn the whole design process.

In the first part of this course, you will learn

about the basics and general concepts of wind loading on structures within our practical and real-life example and also I will explain about how to calculate the wind parameters and where in the code I am getting these values from. These parameters include

- Regional wind speed for different areas of the country,

-Terrain/height multiplier and explaining the definition of different train categories,

- Defining Importance level of the buildings and return period of the wind considering the occupancy and use of the building

- Wind direction multiplier,

- Hill-shape multiplier,

- Shielding multiplier

- Site wind speed

- Design wind speed

- Aerodynamic shape factor for different surfaces or parts of the building.

Calculating aerodynamic shape factor requires calculating the external and internal pressure coefficients, area reduction factor, local pressure factor, action combination factor, permeable cladding factor, and dynamic response factor.

These factors have to be determined for windward walls, Leeward walls, sidewalls, roof structure, and cladding surfaces of the walls and roof with respect to wind on 4 major axes of the structure.

- Design wind pressure on structural elements of the walls and roof for different portal frames of this warehouse for the 4 major axes of the structure.

- Frictional Drag forces on Roof and Side Walls.

- How wind pressure changes along the roof and long walls.

In part 2, I will explain:

- Design wind pressure on doors and windows and how the size of the opening can impact the net wind pressure on wall and roof surfaces.

- Design wind pressure on wall claddings and supporting structures and how to calculate localized wind pressures on walls claddings

- Design wind pressure on roof claddings and supporting structures and how to calculate localized wind pressures on roof claddings.

- Evaluating the impact of the big openings on internal and net wind pressure on cladding surfaces of the roof and walls.

- How wind pressure changes along the roof and long walls.

- Summary of the net wind pressure on different areas of the roof.

By the end of these two courses, you will learn about the fundamental and full and detailed process of calculating the wind pressure for structural members and claddings surfaces of the walls and roof of a steel-framed warehouse.

My goal is to add value to my students by conveying my professional/practical experience as well as explaining the theoretical concept behind the design, so please do not hesitate to ask if you ask any questions through the message box here or any other social media links which are provided in our page.

Also, you will have lifetime access to the course content which means you will receive all future updates and additions free of charge.

What's inside

Syllabus

Introduction

Part 1 - Introduction

Part 2 - Basic Concept and Structure definition

Part 3 - Design and Regional Wind Speed definitions

Part 4 - Calculating Design and Site Wind Speed for 4 major axes of Wareouse

Part 5 - Aerodynamic shape factor (External Pressure Coefficient)

Part 6 - Aerodynamic shape factor (Local pressure factor)

Part 7 - Aerodynamic shape factor (Internal Pressure Coefficient)

Part 8 - Aerodynamic shape factor (Permeable cladding and Action Combination Factors)

Part 9 - Frictional Drag Forces

Part 10 - Design Wind Pressure on Portal Frames (North-East wind)

Part 11 - Design Wind Pressure on Portal Frames (South-West wind)

Part 12 - Design Wind Pressure on Portal Frames (North-West wind)

Part 13- Design Wind Pressure on Portal Frames (South-East wind)

Activities

Be better prepared before your course. Deepen your understanding during and after it. Supplement your coursework and achieve mastery of the topics covered in Design Wind Loading on a Steel Frame Warehouse - Part 1 of 2 with these activities:

Review Structural Mechanics Fundamentals

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Reviewing structural mechanics fundamentals will help you better understand how wind loads affect the steel frame warehouse.

Browse courses on Structural Mechanics

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Review basic concepts of stress, strain, and bending moments.
Practice calculating reactions and internal forces in beams and frames.

Read 'Structural Analysis' by R.C. Hibbeler

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Reading this book will provide a solid foundation in structural analysis, which is essential for understanding wind loading calculations.

View Structural Analysis on Amazon

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Read chapters related to structural analysis methods.
Work through example problems to reinforce understanding.

Calculate Wind Pressure for Simplified Structures

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Practicing wind pressure calculations on simplified structures will reinforce your understanding of the AS1170.2 standard.

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Find examples of simple building geometries online.
Calculate wind pressures using the AS1170.2 standard.
Compare your results with online calculators or software.

Four other activities

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Create a Wind Load Calculation Spreadsheet

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Creating a spreadsheet to automate wind load calculations will solidify your understanding of the process and improve efficiency.

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Identify all the parameters required for wind load calculation.
Implement the AS1170.2 formulas in the spreadsheet.
Test the spreadsheet with different building configurations.

Study 'Wind Loading of Structures' by J.D. Holmes

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Studying this book will provide a deeper understanding of wind loading principles and their application to structural design.

View Putting Knowledge to Work on Amazon

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Read chapters related to wind characteristics and pressure distributions.
Analyze case studies of wind loading on different structures.

Design Wind Bracing for a Small Structure

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Designing wind bracing for a small structure will allow you to apply your knowledge of wind loading and structural design in a practical setting.

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Select a small structure, such as a shed or carport.
Calculate wind loads on the structure using AS1170.2.
Design wind bracing to resist the calculated wind loads.
Check the adequacy of the bracing using structural analysis software.

Prepare a Presentation on Wind Load Design

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Preparing a presentation on wind load design will help you consolidate your knowledge and communicate it effectively to others.

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Outline the key concepts of wind load design.
Prepare slides with clear explanations and diagrams.
Practice delivering the presentation to a colleague or friend.

Career center

Learners who complete Design Wind Loading on a Steel Frame Warehouse - Part 1 of 2 will develop knowledge and skills that may be useful to these careers:

Structural Engineer

A structural engineer analyzes, designs, and oversees the construction of structures, ensuring their safety and stability. This course helps structural engineers by detailing how to calculate design wind pressures for structural members and cladding surfaces of steel-framed warehouses. The course specifically covers the calculation of wind parameters, including regional wind speed, terrain/height multiplier, importance level, and wind direction multiplier. A structural engineer will find that this course provides insight into aerodynamic shape factors, external and internal pressure coefficients, and frictional drag forces. This course will be useful for any structural engineer working on warehouse design.

See salaries and explore the career path for Structural Engineer

Architectural Engineer

Architectural engineers apply engineering principles to the design, construction, and operation of buildings. The course provides a detailed explanation of how to calculate design wind pressures for structural members and cladding surfaces, which is essential for ensuring the structural integrity of buildings. An architectural engineer will learn about calculating wind parameters like regional wind speed, terrain/height multipliers, and importance levels. This course will be useful to any architectural engineer working on warehouse design because it explains aerodynamic shape factors and how wind pressure changes along the roof and walls.

See salaries and explore the career path for Architectural Engineer

Civil Engineer

Civil engineers design, construct, supervise, and maintain infrastructure projects and systems, including roads, buildings, airports, tunnels, bridges, and water and sewage systems. This course helps civil engineers by detailing the process of calculating design wind pressures, especially for steel-framed warehouses. A civil engineer will learn how to determine wind parameters, such as regional wind speed, terrain, height multipliers, and importance levels of buildings. This course may guide civil engineers in determining aerodynamic shape factors and understanding the impact of openings on wind pressure. This course may be useful to any civil engineer wanting to specialize in structural design.

See salaries and explore the career path for Civil Engineer

Construction Manager

Construction managers plan, coordinate, budget, and supervise construction projects from start to finish. A deep understanding of wind loading is crucial for construction managers, as it directly impacts the safety and durability of structures. This course helps construction managers by detailing how to calculate design wind pressures for structural members and cladding surfaces. A construction manager will gain insight into the nuances of wind parameters and aerodynamic shape factors. This course will be useful for construction managers who want to understand the structural elements of warehouse construction.

See salaries and explore the career path for Construction Manager

Building Inspector

Building inspectors examine buildings and other structures to ensure compliance with building codes, zoning regulations, and contract specifications. This course teaches the calculation of design wind pressures for structural members and cladding surfaces. This information can help building inspectors verify that structures are designed to withstand wind loads, ensuring public safety. A building inspector will find the details on wind parameters useful, along with the explanation of aerodynamic shape factors. This course may be useful to any building inspector overseeing steel-framed warehouse construction.

See salaries and explore the career path for Building Inspector

Engineering Consultant

Engineering consultants provide expert advice and guidance on engineering projects to clients. The course, focusing on calculating design wind pressures for steel-framed warehouses, provides specific knowledge that can be applied in consulting projects involving structural design. Engineering consultants may be interested in the course's detailed explanation of wind parameters, aerodynamic shape factors, and pressure coefficients when advising clients on warehouse projects. This course may be useful for engineering consultants looking to specialize in warehouse design.

See salaries and explore the career path for Engineering Consultant

Wind Energy Engineer

Wind energy engineers design, develop, and maintain wind energy systems and related infrastructure. While the course focuses on wind loading on buildings rather than energy generation, the fundamental principles of wind behavior and pressure calculation are relevant. The detailed explanation of wind parameters, such as regional wind speed, terrain/height multipliers, and wind direction multipliers, can be valuable. This course may be useful to wind energy engineers seeking to broaden their understanding of wind forces and their impact on structures.

See salaries and explore the career path for Wind Energy Engineer

Claims Adjuster

Claims adjusters investigate insurance claims and determine the appropriate settlement. Knowledge of how wind affects structures is crucial when assessing damage from storms or other weather-related events. This course, by detailing the calculation of design wind pressures, can help claims adjusters better understand the potential causes and extent of damage. This course may be useful to claims adjusters specializing in property damage assessment.

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Aerospace Engineer

Aerospace engineers design, test, and oversee the manufacturing of aircraft, spacecraft, satellites, and missiles. The principles of aerodynamics and fluid dynamics, covered in the course, are highly relevant to this field. The detailed explanation of wind parameters, aerodynamic shape factors, and pressure coefficients can be valuable. The course may be useful to aerospace engineers who want to expand their knowledge with structural engineering.

See salaries and explore the career path for Aerospace Engineer

Research Scientist

Research scientists plan and conduct experiments and analyze data related to engineering projects. The course on calculating design wind pressures for structural members can provide valuable insights into real-world applications of fluid dynamics and structural mechanics. The course's focus on wind parameters, aerodynamic shape factors, and pressure coefficients offers a practical context for theoretical models. This may be useful for research scientists in structural or aerospace engineering wanting to validate their models with real-world design considerations.

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Mechanical Engineer

Mechanical engineers design, develop, test, and manufacture mechanical devices and systems. While the course focuses on structural wind loading, the underlying principles of fluid dynamics and pressure calculation are relevant. A mechanical engineer may find the explanation of wind parameters and aerodynamic shape factors useful. This course may be useful for mechanical engineers involved in structural design.

See salaries and explore the career path for Mechanical Engineer

Risk Analyst

Risk analysts assess and manage risks that could impact an organization. Understanding wind loads on structures is relevant to assessing the potential for damage and financial loss due to extreme weather events. This course can help risk analysts understand the factors that contribute to wind-related risks in warehouse structures. This course may be useful to risk analysts focused on property insurance.

See salaries and explore the career path for Risk Analyst

Urban Planner

Urban planners develop plans and programs for the use of land. While not directly related to structural engineering, wind loading can influence decisions about building placement and orientation. The course, which details the calculation of design wind pressures, may provide useful insights into the impact of wind on urban structures. An urban planner may also find discussion of regional wind speeds and terrain/height multipliers relevant to overall urban design. This course may be useful for urban planners involved in large-scale developments.

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Sustainability Consultant

Sustainability consultants advise organizations on how to operate in a more environmentally responsible way. While this course may not be directly related to sustainability, understanding wind loads and structural design can contribute to more efficient building practices. This course may be useful to sustainability consultants seeking to learn about structural engineering.

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Product Designer

Product designers conceptualize and design new products, considering both aesthetics and functionality. While not directly related, understanding structural integrity and wind resistance can inform the design of outdoor products or building components. The course, which details the calculation of design wind pressures, may provide insights into the forces that products need to withstand. This course may be useful for product designers creating outdoor structures.

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Design Wind Loading on a Steel Frame Warehouse - Part 1 of 2

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