Australian Structural Engineering Course: Steel, RCC& Timber from Udemy

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Syllabus

Structural Analysis and Design of Platform Floor with Hot Rolled Sections

Introduction to the Structural Steel Mezzanine floors in Australia

Modelling of Mezzanine Floor in ETABS

Modelling of Secondary beams and Deck floors

Application of Seismic loads in ETABS as per AS1170 on Mezzanine Steel Structure

Defining Load Combinations, Mass Source and P-Delta in ETABS

Design Results and Verification in ETABS

Steel Design as per AS4100:2020 and Composite beam Design

Design of Structural Steel Mezzanine with Cold Form Members

Introduction to the Cold Form Steel members

Purlins and Girts in PEMB System - Detailed Explaination

Understanding Moment Capacity Tables for Purlins and Girts

Structure Design of C-Purlins in Ex-Facta Software - Strength and Serviceability

Structure Design of Purlins for 5 KPa Imposed Load on Mezzanine

Modelling of Structure Steel Mezzanine in ETABS

Defining Load Patterns in ETABS

Defining Load Combinations as per AS1170

Design Calculations Check for Steel Structure as per AS4100:2020

Design of Anchors to support the Mezzanine on the RCC Floor

Design of Steel Structural Pipe Racks with Connection Design

Introduction to Structural Steel Pipe Racks

Modelling of Structural Steel Piperacks with Plan and Elevation Bracings

Application of Dead Loads, Piping loads and Seismic Loads to the Pipe Rack

Preliminary Design for Gravity and Piping Loads as per AS4100:2020

Calculation of Wind Speed as per AS1170.2 for Open Steel Structure

Application of Wind Load on Open Steel Structures

Strength and Serviceability Design of Pipe Racks Steel Structure

Design of base plate for Axial load and Bending Moment as per AS4100:2020

Design of RCC Pedestals as per AS3600:2018

Design of RCC Foundations for Axial Load and Bending Moment

Design of Moment Connection for Steel Moment Resistant Frame

Design of Shear Connection for Steel Frame of Pipe Rack

Design of Bracing connection as per AS4100:2020

Design of Structural Steel Foot Over bridge as per AS4100:2020

Introduction to Structural Steel Foot Over Bridges Constructed in Australia

Design of Cold Form Beams to support Deck

Modelling of Structural Steel Foot Over Bridge in ETABS

Application of Dead Loads, Live Loads and Seismic Loads on the foot Over Bridge

Calculation of Wind Load on Foot over bridge Structure as an Open Structure

Load Combinations as per AS1170 for Wind and Seismic Loads

Design of Steel Structure of Foot Over Bridge as per AS4100:2020

Design of Structural Steel Connections as per AS4100:2020 for Foot Over Bridge

Introduction to Structural Steel Section Types and Properties - Basics

Introduction to Uniform Beams and Uniform Columns - Structural Steel Members

Understanding Second Moment of Area & Sectional Modulus

Rectangular Hollow Sections, Square Hollow & Circular Hollow Sections

Capacity Reduction Factors for Bending, Shear and Compression as per AS4100

Introduction to Steel Buildings in Australia - Steel Structural System Followed

PEMB Steel Buildings - Pre-Engineered Metal Building systems and components

Different Structural Steel systems and their behavior

Detailed Calculations of Steel Structure as per AS4100: 2020 - Hand calculation

Understanding Different types of Members in Steel Structures

Design of Tension Members as per AS4100

Design of Compression members as per AS4100:2020

Design Calculations in ETABS for Compression members with Hand Calculation

Design of Laterally Supported Structural Steel Beams

Design of Laterally Unsupported Structural Steel beams

Values of Kt, Kl and Kr for Structural Steel beams

Bending capacity of Laterally Unsupported Steel beams

Calculation of Shear Capacity of Structural Steel beams

Detailed Calculations in ETABS for Laterally Unsupported Steel beams

Design of Cantilever Steel beams with Detailed Calculations

Design of Beam-Columns as per AS4100:2020

Calculations of Structural Steel Connections Components - Bolted and Welded

Types of Structural Steel Bolts - Different Grades and Strength Parameters

Snug Tight, Bearing Type and Friction Type Bolts as per AS4100:2020

Tension, Shear and Bearing Capacity of Steel Bolts

Thumbrules to calculate Capacity of Structure Steel Bolts

Calculation of Capacity of Weld for different grades and thickness

Difference in GP- SP - General purpose and Structural purpose Welding

Design of Structural Steel Pin as per AS4100

Design of Mechanical and Chemical anchors as per AS5216:2021

Mechanical and Chemical Anchors Meaning and Detailed Explanation

Types of Failure in Mechanical and Chemical Anchors

Detailed discussion on Mechanical and Chemical Anchors

Detailed Design Calculations of Anchors as per AS5216:2021

AS1170.0 - Structure Design Actions and General Principles Explanation

Introduction to Type of Loads for AS/NZ and Section-1 of AS1170

Importance level of Buildings and Structures with Probability of Exceedance-AUST

Importance level of Buildings and Structures with Probability of Exceedance-NZS

Stability and Strength Load Combinations including Long Term and Earthquake

Serviceability Limit State and Combination of Actions including Criteria

AS1170.2 Design of Structures with Wind Actions (Practical Example)

An introduction to AS1170.2, including its Applicability and Basics

Site Wind Speed, Regional Wind Speed, and Design Wind Speed (Vsit,β, Vdes,θ, Vr)

Wind Pressure, Friction Drag Forces, and Debris Impact Loading

Regional Wind Speed (Vr), Climate Change Multiplier (Mc) and (Md)

Terrain Category and Terrain/Height Multiplier (Mz,cat)

Shielding Multiplier (Ms) with Practical Example as per AS1170.2.21

Lee Multiplier (Mlee) Calculation for New Zealand

Topographic Multiplier (Mt) and Hill Shape Multiplier (Mh) for Hills

calculation of Regional Wind Speed, Wind Pressure & Topographic Multiplier (Mt)

Explanation of Aerodynamic Shape Factor (Cshp)

Calculation of Cpe and Cpi (External and Internal Pressure Coefficient)

Internal Pressure Coefficient Cpi - Meaning and Detailed Explanation

Internal pressure Cpi Values for Different Opening Areas and Volume Factor kv

External Pressure Coefficient Cpe - Roofs and Walls

Cpe and Cpi Calculation Example with reference to the AS1170.2.2021

Calculation of Aerodynamic Shape Factor Cshp as per AS1170.2-2021 (Annexure B)

Calculation of Aerodynamic Shape Factor for Hoarding Structure (Cshp)

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 Australian Structural Engineering Course: Steel, RCC& Timber with these activities:

Review AS/NZS 1170.0

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Review the fundamental principles outlined in AS/NZS 1170.0 to establish a solid foundation for understanding subsequent design standards.

Browse courses on Structural Design

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Obtain a copy of the AS/NZS 1170.0 standard.
Read through the sections on general principles and design actions.
Summarize key concepts and definitions.

Study 'Reinforced Concrete Structures' by Warner

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Deepen your understanding of reinforced concrete design principles, particularly relevant for foundation design.

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Obtain a copy of 'Reinforced Concrete Structures'.
Focus on chapters related to foundation design and material properties.
Review example problems and design calculations.

Read 'Steel Designers' Handbook'

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Study a comprehensive handbook on steel design to gain a deeper understanding of the principles and practices used in the field.

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Acquire a copy of the Steel Designers' Handbook.
Read the chapters relevant to the course syllabus.
Work through the example problems provided in the book.

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Practice Wind Load Calculations

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Reinforce your understanding of wind load calculations by working through various practical examples based on AS1170.2.

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Find several example structures with varying geometries.
Calculate the wind loads on each structure using AS1170.2.
Compare your results with existing solutions or consult with peers.

Explore ETABS Tutorials

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Enhance your proficiency in ETABS by following online tutorials that demonstrate modeling and analysis techniques specific to steel structures.

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Search for ETABS tutorials focusing on steel structure design.
Follow the tutorials to model and analyze example structures.
Experiment with different modeling techniques and settings.

Design a Simple Steel Mezzanine

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Apply your knowledge by designing a simple steel mezzanine structure, including member selection and connection design, according to AS4100.

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Define the requirements for the mezzanine structure.
Select appropriate steel sections for beams and columns.
Design the connections between members.
Prepare a design report with calculations and drawings.

Contribute to a Structural Engineering Forum

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Reinforce your learning by answering questions and participating in discussions on online structural engineering forums.

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Find an active online forum for structural engineers.
Browse the forum for questions related to steel design or Australian standards.
Contribute thoughtful and helpful answers to the questions.

Career center

Learners who complete Australian Structural Engineering Course: Steel, RCC& Timber 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 Australian Structural Engineering Course helps structural engineers deepen their understanding of Australian standards and practices, specifically in steel, reinforced concrete, and timber design. The course's focus on AS4100:2020, AS5216:2021, and AS1170 equips engineers with the knowledge to design durable structures. Structural engineers can benefit from the course's modules on wind and seismic actions, connection design, and the use of software like ETABS, which are directly applicable to real-world structural design projects. The course also provides important knowledge regarding mechanical and chemical anchors. The course is particularly useful to structural engineers working in Australia or those seeking to align their skills with Australian standards.

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Bridge Engineer

Bridge engineers specialize in the design, construction, and maintenance of bridges. They are responsible for ensuring the structural integrity and safety of these critical infrastructure components. This Australian Structural Engineering Course helps bridge engineers enhance their knowledge of Australian standards related to steel and concrete design. The course's modules specifically addressing wind and seismic actions are directly relevant to bridge design, where these environmental factors play a significant role. Bridge engineers may find the section on foot overbridge design as per AS4100:2020 particularly beneficial. This structural steel design course provides important information for those looking to make bridges well. This course provides important knowledge regarding mechanical and chemical anchors.

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Steel Detailer

Steel detailers create detailed shop drawings for steel structures, providing the information needed for fabrication and erection. A strong understanding of steel design principles and connection details is essential for producing accurate and constructible drawings. Attending the Australian Structural Engineering Course helps steel detailers enhance their knowledge of Australian standards for steel design, specifically AS4100:2020. The course's modules on connection design, bolted and welded connections, and steel section types are directly relevant to the work of a steel detailer. This may be incredibly helpful in producing shop drawings that meet the required standards and ensure the structural integrity of steel structures. This course provides important knowledge regarding mechanical and chemical anchors.

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Structural Designer

A structural designer creates detailed plans and drawings for structures, often working under the supervision of a structural engineer. This Australian Structural Engineering Course helps structural designers gain a deeper understanding of the principles behind structural design and the application of Australian standards. The course provides structural designers with a practical understanding of steel, reinforced concrete, and timber design, improving their ability to create accurate and efficient designs. Structural designers can benefit from the course's modules on connection design, wind load calculations, and seismic actions, which are essential for producing comprehensive structural drawings. The course is especially beneficial for structural designers seeking to work on projects adhering to Australian standards. This course provides important knowledge regarding mechanical and chemical anchors.

See salaries and explore the career path for Structural Designer

Civil Engineer

Civil engineers design, construct, supervise, and maintain infrastructure projects, including roads, bridges, buildings, and water systems. While civil engineering encompasses a broad range of specializations, knowledge of structural design is often crucial, especially for those involved in building and bridge projects. This course helps civil engineers become familiar with Australian standards for structural steel, reinforced concrete, and timber design. Civil engineers apply principles learned from modules covering wind and seismic load calculations, connection design, and the application of AS4100:2020. The course may be particularly helpful for civil engineers seeking to work on projects that require adherence to Australian standards, enabling them to design and analyze structures with confidence. This course provides important information on wind actions, snow and ice actions, and seismic actions.

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Building Inspector

Building inspectors examine buildings and structures to ensure they comply with building codes and regulations. A solid understanding of structural engineering principles is essential for identifying potential safety hazards and ensuring the structural integrity of buildings. This Australian Structural Engineering Course helps building inspectors enhance their knowledge of structural design and Australian standards, enabling them to perform more thorough and accurate inspections. The course modules on steel, reinforced concrete, and timber design, as well as wind and seismic load calculations, provide valuable insights for assessing the structural soundness of buildings. This course goes in depth regarding wind and seismic actions.

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Project Engineer

Project engineers manage and coordinate engineering projects, ensuring they are completed on time, within budget, and to the required specifications. While project engineers may not always specialize in structural engineering, understanding structural principles is beneficial, especially for construction-related projects. This Australian Structural Engineering Course helps project engineers gain a broader perspective on the structural aspects of projects, improving their ability to communicate with structural engineers and make informed decisions. Project engineers are able to use AS4100 and AS1170 to better understand wind and seismic load considerations. The course may be particularly useful for project engineers seeking to work on structural projects that require adherence to Australian standards. This course provides important knowledge regarding mechanical and chemical anchors.

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Construction Manager

Construction managers oversee the planning, coordination, and execution of construction projects. Although they might not directly perform structural design calculations, a strong understanding of structural principles and standards is essential for effective project management. This Australian Structural Engineering Course helps construction managers gain insights into the structural aspects of construction, enabling them to better coordinate with engineers and subcontractors. The course, by going over AS4100 and AS1170, promotes a deeper understanding of wind and seismic load considerations. Construction managers are able to make better decisions related to budgeting, scheduling, and quality control. The course may be particularly useful to construction managers working on projects that require adherence to Australian standards. This course provides important knowledge regarding mechanical and chemical anchors.

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Quality Control Engineer

Quality control engineers ensure that engineering projects and products meet specific quality standards and regulations. In structural engineering, this involves verifying that materials, construction processes, and final structures adhere to safety and performance requirements. The Australian Structural Engineering Course could help quality control engineers become conversant in Australian standards for structural steel, reinforced concrete, and timber design. The course’s focus on codes like AS4100 and AS/NZS 1170 may provide a framework for assessing structural integrity and compliance. The knowledge gained from this course about wind load calculations and connection design could be invaluable for quality control engineers.

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Architectural Engineer

Architectural engineers integrate architectural design with engineering principles, focusing on the structural and mechanical systems of buildings. This Australian Structural Engineering Course may help architectural engineers improve their understanding of structural design principles and Australian standards. The course content builds a strong foundation for making informed decisions about structural systems, load calculations, and connection details. The course may be particularly helpful for architectural engineers working on projects that require adherence to Australian standards, enabling them to collaborate effectively with structural engineers and ensure the overall safety and efficiency of building designs. The course goes in depth regarding wind and seismic actions.

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Structural Drafter

Structural drafters prepare detailed drawings and plans for structures, based on the designs and specifications provided by structural engineers. A good understanding of structural engineering principles and relevant codes is crucial for producing accurate and clear drawings. This Australian Structural Engineering Course may help structural drafters learn about Australian standards for structural steel design and reinforced concrete. Structural drafters may take advantage of the course to understand topics such as connection design and the use of AS4100. This course is useful for structural drafters working in Australia or with Australian standards.

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CAD Technician

CAD technicians use computer-aided design software to create technical drawings and models for engineering and construction projects. While CAD technicians may not be responsible for structural design calculations, a basic understanding of structural principles and standards can improve their ability to create accurate and useful drawings. This Australian Structural Engineering Course helps CAD technicians gain a broader perspective on the structural aspects of projects, enabling them to better understand design requirements and produce higher-quality drawings. By becoming familiar with Australian Standards and reinforced concrete, the CAD technician will be more effective. The course may be useful to technicians working on projects that require adherence to Australian standards. This course provides important knowledge regarding mechanical and chemical anchors.

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Research Engineer

A research engineer investigates and develops new engineering technologies and methods. Within structural engineering, this could involve exploring innovative materials, design techniques, or analysis methods. Often this role requires an advanced degree. The Australian Structural Engineering Course may help a research engineer gain a strong foundation in Australian structural standards and practices. The course’s exploration of steel, RCC, and timber design under AS4100 and AS/NZS 1170 provides context for evaluating current practices and identifying areas for improvement. Research engineers exploring the seismic and wind-resistant structures may find value in it. Overall, the course may give a deeper understanding of practical structural engineering which grounds research efforts in real-world needs.

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Materials Engineer

Materials engineers research, develop, and test materials used in engineering applications. In structural engineering, they focus on the properties and performance of materials like steel, concrete, and timber, ensuring they meet the required strength, durability, and safety standards. The Australian Structural Engineering Course may help materials engineers become more familiar with Australian standards for structural design and material selection. This course may provide insights into how materials are used in real-world structural applications. These materials engineers are better prepared to innovate in materials engineering.

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University Lecturer

University lecturers teach engineering principles and practices to undergraduate and graduate students. They develop course materials, deliver lectures, assess student work, and conduct research in their area of expertise. Lecturers would typically need an advanced degree. The Australian Structural Engineering Course can help instructors stay up-to-date with current industry standards. Lecturers can gain in-depth knowledge of structural steel, reinforced concrete, and timber design to enrich their teaching and research. By completing the course, lecturers can enhance their ability to prepare students for successful careers in structural engineering, especially in Australia.

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Reading list

We've selected one books that we think will supplement your learning. Use these to develop background knowledge, enrich your coursework, and gain a deeper understanding of the topics covered in Australian Structural Engineering Course: Steel, RCC& Timber.

Putting Knowledge to Work

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This handbook comprehensive resource for structural steel design, covering a wide range of topics relevant to the course. It provides detailed explanations, design examples, and practical guidance for applying Australian standards. It serves as a valuable reference for both students and practicing engineers. The book offers in-depth coverage of topics such as connection design, member design, and overall structural analysis, complementing the course material.

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Australian Structural Engineering Course

Steel, RCC& Timber

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