engineering training institute australia · 1.00 - 1.30 lunch break calculators required paul uno...

Presents the following courses in Australia March 2020

www.etia.net.auABN 27 830 322 080

8/20

ENGINEERING TRAINING INSTITUTE AUSTRALIA

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ABN 27 830 322 080

August and September 2020 Courses

LIVE STREAMED COURSE LIST

• Tue 18 + Wed 19 August 2020 Residential Slabs & Footings Design Workshop

• Tue 25 August 2020 Forensic Engineering Workshop

• Wed 26 August 2020 Cement & Concrete Engineering Technology Workshop

• Tue 1 September 2020 Accounting & Management for Engineers Course

• Tue 8 September 2020 Metallurgy Materials Workshops

• Thu 10 September 2020 Concrete Pipes & Pipeline Design Workshop

• Tue 15 September 2020 FRP Structural Design Workshop

• Thu 17 September 2020 Repair & Protection Workshop: Concrete, Steel & Masonry Structures

• Tue 22 September 2020 Finite Element Analysis Workshop

• Thu 24 September 2020 Vibration & Fatigue Engineering Workshop

• Tue 29 + Wed 30 September Process Piping (Pressure) Design Workshop

ANNUAL SPONSORS OF ETIA

8/20

IMPORTANT NOTICE

• ALL COURSES WILL BE LIVE STREAMED (AEST).

• PLEASE REFER TO THE REGISTRATION FORM AT THE BACK OF THIS CATALOGUE

(OR THE ETIA WEBSITE) FOR FURTHER DETAILS ON LIVE STREAMING.

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WORKSHOP SUMMARY This workshop has been specifically designed for engineering managers and consulting engineers, to assist them in running a more efficient and effective team or business.

After attending this course, you should have an understanding of:

- Tax deductions prescribed for the engineering profession. - The pros and cons of various trading structures. - Techniques and strategies for achieving goals and objectives. - Insurance as a means of risk mitigation. - Policy and procedure development to ensure quality control. - How to read and understand financial statements. - Setting employee charge rates to ensure a return on investment.

If you provide consulting services or have aspirations for senior management, then this is a must attend event.

1.30 - 3.00 Session 4 (Insurance Brokers) - INSURING AGAINST RISK AND TAX DEDUCTIBILITY OF PREMIUMS • Different insurances to be considered:

o Professional Indemnity o Public Liability o Workers Compensation o Income Protection o Total Permanent Disability o Life Cover o Critical Illness o Keyman

o Business Continuity

3.00 - 3.30 Afternoon Tea

3.30 - 5.00 Session 5 (Vincent Uno) - FINANCIAL STATEMENT ANALYSIS AND CHARGE RATES

PROGRAMME (8.30 - 9.00 Registration) • The Peter Principle • Reading and understanding the components of financial statements:

o Compilation Report o Directors Declaration o Balance Sheet o Profit and Loss Statement o Statement of Equity

• Practical application of ratio analysis to determine team/business’s profitability, return on capital, liquidity, borrowing capacity and debtor collectability.

• Techniques to control cash flow and work in progress. • The calculation charge rates and the salary cost multiplier to ensure

that overall team/business profitability targets have the ability to be met and that employee output performance can be benchmarked.

5.00 - 5.15 Certificate of Attendance & Feedback sheets

9.00 - 9.45 Session 1 (Vincent Uno) - ATTRIBUTES OF SUCCESSFUL MANAGERS, TRADING STRUCTURES AND TAX PLANNING • Attributes of a successful manager or consulting engineer. • Engineers Australia’s Code of Ethics and what it means for you. • Maximise your tax refunds after reviewing the ATO’s occupation

specific deduction guidelines for the engineering profession. • The pros and cons of the following trading structures, and whether a

restructure should be considered.

o Sole Trader o Partnership o Company o Trust

9.45 - 10.30 Session 2 (Vincent Uno) - STRATEGIC AND BUSINESS PLANNING FOR MANAGERS AND CONSULTING ENGINEERS

• Preliminary planning process using S.W.O.T Analysis • The 10 step strategic planning process • Defining and achieving business goals and objectives using the

S.M.A.R.T principle. • Implementation and design of Action Plans • Setting and monitoring Key Performance Indicators (KPIs).

10.30 - 11.00 Morning Tea

11.00 - 12.30 Session 3 (Vincent Uno) - MANAGEMENT POLICIES, PROCEDURES AND RISK MITIGATION

• Developing Policies and Procedures • Client Engagement Letters • Risk Mitigation in the areas of:

o Human Resources o Information Technology and Cyber Security o Email Correspondence

• Key focus areas that all businesses should maintain quality control.

12.30 - 1.30 Lunch (Provided at Venue)

FURTHER INFORMATION • Office (02) 9899 7447

• Mobile 0413 998 031 • Email [email protected]

VINCENT UNO BCom CPA JP Tax Agent • Director -

Engineering Accountants and Advisors.

RAOUL BASILE • Woodina

Underwriting Agency Pty Ltd

• Professional Lines Underwriting Manager.

COURSE COST • 1 day course – $670 pp

DATES, VENUES & REGISTRATION • Registration form (back of catalogue) • Visit our website www.etia.net.au

JOEL EDELMAN • Director - Principal Edge

Financial Services • Helps clients to protect & build

their wealth through succession planning, ownership & key-person protection.

Live streamed via

Cancellations made more than 5 working days prior to a course will incur a 20% processing fee of the full registration amount. Cancellations made 5 working days or less will incur forfeiture of the full registration fee.

ACCOUNTING & MANAGEMENT FOR ENGINEERS COURSE


WORKSHOP SUMMARY This course is primarily aimed at engineers who wish to understand cement and concrete at a more professional technical level.

Emphasis on this course will be directed to more prominent engineered structures (eg. High Rise, Bridges etc) and their respective specifications and codes (eg. B80 Bridge Spec, AS3600, AS5100, AS1379).

Design life requirements for various structures will be addressed (eg. 50 year design life for normal structures vs 100 year design life for prominent structures).

PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed)

1.30 - 3.00 Session 3 - CONCRETE PROPERTIES & TESTS VS SPECIFICATIONS (eg. B80 Bridge Spec) • Plastic Shrinkage Cracking principles (eg. Bleed evaporation rates vs

Weather conditions vs APP’s) • Plastic Shrinkage Cracking potential, determination using the UNO

evaporation equations and/or ACI nomographs • Plastic settlement factors and identification of these types of cracks • Thermal Cr5acks in concrete – what factors determine the potential

for thermal cracking • Long Term Concrete Shrinkage determination and Code limitations

on crack size (AS2327 vs AS3600 vs AS5100 vs B80) • Miscellaneous factors: curing, setting time, strength development vs

time, concrete maturity, permeability vs porosity, VPV, fibres in concrete, permeability, slump drop vs spread, creep, impact rebound testing (Schmidt hammer).

• Tutorial exercises and solutions provided

3.00 - 3.15 Afternoon Break

9.00 - 11.00 Session 1 - CEMENT & SUPPLEMENTARY CEMENTITIOUS

MATERIALS (Properties & Reactions) • Portland cement types – General Purpose, Blended, Low Heat, High

Early Strength, Low Shrinkage, Sulphate Resistant, Off-White • Outlining the 4 main phases of cement (ie. C3S, C3A, C2S and C4AF)

and their effects on cement properties. • Non-Standard cement types (eg. High Alumina cements and

geopolymers) • Supplementary cementitious materials – Flyash vs slag vs silica fume,

including formulas showing the pozzolanic reactions • Green Star Ratings and Sustainability issues • Tutorial exercises and solutions provided

11.00 - 11.15 Morning Break

3.15 - 5.00 Session 4 - CONCRETE DURABILITY & CORROSION vs SPECIFICATIONS (eg. B80 Bridge Spec) • Ion Diffusion Process • Carbonation (eg. Klopfer formula) • Chloride Ingress (eg. Fick’s formula) • Corrosion process and steel corrosion formulas • Effective Chloride Transport Coefficient determination using

Nordtest NT Build 443 (as required by B80) • Non-Steady State Migration Coefficient determination using

Nordtest NT Build 443 (as required by B80) • Acid-Sulphate Soils • Alkali Aggregate Reaction AAR • Tutorial exercises and solutions provided

Certificate of Attendance will be emailed

11.15 - 1.00 Session 2 - CONCRETE MIX DESIGN (Theory & Practice) • British Method vs Trial Mix Method vs ACI Method (including a

detailed worked example) • Water to Cement Ratio vs Compressive Strength vs Permeability • Statistical Parameters (eg. Characteristic strength ƒ’c vs mean

strength ƒcm (target strength), standard deviation σ, coefficient of variation COV)

• Operating Characteristics Curves vs Optimum mix design • Effects of Admixtures (eg. Accelerators, retarders, water-reducers,

superplasticisers, air entraining agents, corrosion inhibitors) • Tutorial exercises and solutions provided

1.00 - 1.30 Lunch Break

PAUL UNO BE MBdgSc MIEAust CPEng NER RPEQ APEC Engineer IntPE(Aus)

Previously • NSW Senior Engineer (Cement & Concrete Association of Australia CCAA) • NSW Technical Manager (CSR Readymix - now Holcim) • Materials Engineer (Boral)

Event Sponsors: NSW and VIC

FURTHER INFORMATION • Office (02) 9899 7447 • Mobile 0413 998 031

• Email

[email protected]



CALCULATORS REQUIRED

Live streamed via

CEMENT & CONCRETE ENGINEERING TECHNOLOGY WORKSHOP


NEW COURSE

Event Sponsors: NSW & VIC

PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed) 1.30 - 3.00 Session 3

- CONCRETE PIPE DESIGN LOADS AND EQUATIONS 9.00 - 11.00 Session 1 - CONCRETE PIPE MATERIALS, MANUFACTURE, PIPE TYPES AND TESTING

• History of pipe formulas and the people behind these famous equations e.g. Marston, Spangler, Moser, Folkman etc.

• Pipeline definition of trench vs embankment. • Formulas in AS/NZS3725-2007 (derivations provided). • Trench theory, positive and negative projection in embankments

(both complete and incomplete), settlement ratios, the effect of soil parameters K and u values on the design as well as jacked pipe systems.

• Various loads that can be applied to pipeline systems e.g. Construction loads, Road vehicle loads (including load distribution through fill using Boussinesq equations), Railway loads and Water loads.

• Tutorial


• Materials that are used to manufacture reinforced concrete pipes. • Cement types include GP, SL and HE cement as well as SCM’s

(supplementary cementitious materials) such as flyash. • Reason why some concrete pipes use elliptical steel reinforcement

instead of circular steel reinforcement. • Concrete pipe load class and the requirements of crack control for

testing in accordance with AS/NZS 4058-2007. • Other tests include hydrostatic testing, absorption testing and

durability requirements e.g. impermeability limits, chloride and sulphate concentration limits.


11.15 - 1.00 Session 2 - SOIL PROPERTIES, PIPE SUPPORT AND BEDDING FACTORS

3.15 - 5.00 Session 4 - CONCRETE PIPE DESIGN EXAMPLES AND SOFTWARE • Design worked examples. • Registrants are guided through six (6) worked examples (in detail).

They are then given two (2) detailed tutorial questions to solve by hand using the equations and steps shown earlier.

• Registrants are shown how to quickly solve these same (8) examples using the Concrete Pipe Association of Australia CPAA software program ‘PIPECLASS Version 2.0’

• All attendees are encouraged to bring along their laptops with the software loaded or have it supplied free on the day so that the software tutorial exercises can be carried out.

Certificate of Attendances will be emailed

• Soil classification codes o GW vs SC o Soil Cohesion parameters o Requirements and differences between backfill, ordinary fill and

select fill o Requirements for pipe bedding, haunch zones, side zones and

overlay fill zones o Dry Density Ratio vs Density Index o Bedding Factors o Support Types (eg U vs H vs HS).

• Tutorial



PAUL UNO BE MBdgSc MIE(Aust) CPEng NER APEC Engineer IntPE(Aus)

• Over 40 years of experience in the design and construction industry. • Part-time Senior Lecturer – UNSW and The University of Sydney. • Current chairman of Australian Standards BD-066 Precast & Tilt Up code (AS3850).


• Email

[email protected]


DATES, VENUES & REGISTRATION • Registration form (back of catalogue)

• Visit our website www.etia.net.au

Live streamed via


CONCRETE PIPES & PIPELINE DESIGN WORKSHOP




FINITE ELEMENT ANALYSIS WORKSHOP

WORKSHOP SUMMARY This workshop is designed to give an introduction to engineering analysis using the Finite Element Method (FEM). Finite Element Analysis (FEA) is now widely used in industry, with most mechanical and structural engineers relying on commercially available FEA software on a daily basis to carry out engineering calculations. From structural analysis to harmonic response analysis, stress analysis, fatigue crack propagation studies, impact analysis and post-buckling analysis, FEA is a powerful tool, saving time and providing accurate solutions to engineering problems.

However, although users of FEA have often attended courses on the use of a particular software package, not many are familiar with the underlying theory or many software/code independent practical aspects of working with FEA such as model and element type selection, using analysis checklists, working to codes and standards, FEA report writing and, most importantly, error checking and verification of results. This workshop covers all of these topics and thus provides an in-depth introduction to working with FEA.

A practical demonstration session is also included as part of the workshop to present tips and tricks, CAD model simplification and defeaturing techniques, meshing techniques, error sources and how to minimize errors, and model verification strategies.

1.30 - 3.00 Session 3 - USING FEA IN YOUR ENGINEERING WORK • FEA checklists • Using standards with FEA • Modelling techniques • Working CAD geometry • Validation of results • Error checking • Preparation of FEA reports • Tutorial questions


3.15 - 5.00 Session 4 - PRACTICAL DEMONSTRATIONS USING FEA SOFTWARE • Preprocessing – solution – postprocessing • CAD defeaturing • Element selection • Mesh quality checks • Solution quality checks • Interrogation of model • Linear versus non-linear solver • Buckling, plasticity and impact analysis


PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed) 9.00 - 11.00 Session 1 - INTRODUCTION TO FINITE ELEMENT METHOD

• History of the Finite Element Method • What is finite element analysis (FEA) – and what is it not? • Why do we carry out FEA? • Commercially available packages • Approximation of physical systems • Applications of FEA • General procedure for FEA – preprocessing & postprocessing


11.15 - 1.00 Session 2 - FINITE ELEMENT STIFFNESS MATRIX

• Characteristics of finite elements • Linear spring as a finite element – one dimensional elements • Local and global element coordinate systems • Element stiffness matrix • System assembly in global coordinates • Elastic bar elements • Element shape functions • Tutorial questions


MATT RUDAS MIEAust NER RPEQ CPEng

• Chartered mechanical engineer with over 25 years of experience • Owner principal at Mechsafe Engineering • Specialist FEA and BEA analyst of stress, fatigue and fatigue crack

growth in structures and heavy machinery



• Mobile 0413 998 031 • Email

[email protected]



Live streamed via


WORKSHOP SUMMARY Structures fail. The investigations of these failures are a field of engineering in itself but is also something that many engineers dip in an out of in the course of their work. As another strand of this work an engineer can sometimes be called upon to help stabilise a structure that has been damaged by fire, impacts or some sort of structural failure.

An investigating engineer requires deep experience and a well-rounded understanding of the underlying physical phenomenon, engineering theory, standards, design methodologies and construction process as well as a rigorous approach to investigation and reporting.

By examining fascinating cases from national and international experience, this course will provide some of the tools necessary for an engineer to investigate failed or damaged structures.

Additionally, knowledge of the environments and situations that can lead to failure can help design and construction professionals avoid their own mistakes. This is a form of risk management; it’s far better to learn from someone else’s mistakes than your own!

1.30 - 3.00 Session 3 (Paul Davis) - CASE STUDIES: MATERIALS

The examination of real world failures helps us learn from the past and examine our own practices. With a focus on materials this session includes: • Steel o Large portal frame roof collapse o Walkway collapse o Portal frame in cyclone o Floor dynamic failure o Bridge collapse o Arch collapse

• Concrete o Precast failures o Tilt Up wall collapses o Waterproofing o Ground slabs o Reinforced concrete failures

• Timber o Roof failures o Deflection Failures o Dynamic Failures

• Masonry • Geotechnical o Retaining walls o Residential slabs o Bored pier failures

• Practical exercise


PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed)

9.00 - 11.00 Session 1 (Paul Davis) - INTRODUCTION, SYSTEMIC CAUSES OF FAILURE & THE PHYSICAL INVESTIGATION

After introductions, we examine the human and technical factors that can lead to a structural fault and then look at how we might go about the site investigation the failure or damage. • Systematic Causes: o Education o Experience o Uncertainties o Design environment o Design processes o Chain of responsibility o Construction

• Investigation techniques: o Investigation team o Initial investigation o Dealing with emergency services, professionals, media and

stakeholders. o Safe investigation methodology o Stabilisation – “make safes” o Recording methods o Gathering evidence


3.15 - 5.00 Session 4 (Paul Uno) - CASE STUDIES: ACTIONS We continue our examination of real world failures with a focus on actions. This session includes:

• “Regular” actions: ● “Exotic” actions o Live loads Fire o Wind Water o Snow Material deterioration o Earthquake Impacts

• Practical exercise • Course review

Certificate of Attendance will be emailed 11.15 - 1.00 Session 2 (Paul Davis) - TECHNICAL REPORT WRITING

Technical report writing demands a clarity of approach and style which can be beneficial in fields beyond forensic engineering. The session includes: • Language • Layout • Style • Common mistakes • Professional responsibilities • Logical argument structures • Practical exercise


PAUL DAVIS BE(Civil) MIE(Aust) CPEng NPER • Principal Engineer - Project X Solutions • 30 years of experience in civil and structural design and construction. • Investigated and reported on approximately 2000 damaged or

defective structures.


• Mobile 0413 998 031 • Email

[email protected]



PAUL UNO BE MBdgSc MIE(Aust) CPEng NER RPEQ APEC Engineer IntPE(Aus)

• Over 40 years of design and construction experience. • Part-time Senior Lecturer – UNSW and The University

of Sydney.

Live streamed via



FORENSIC ENGINEERING WORKSHOP


WORKSHOP SUMMARY This workshop is aimed at practicing engineers, consultants and contractors working in the areas of structural design, construction and remediation of reinforced concrete and post tensioned concrete buildings and bridges. The course will provide an overview on the applications of fibre reinforced polymer composites as a strengthening material and the design procedures for FRP strengthening of concrete structures when subjected to flexure, shear and axial loads according to the new AS5100.8 (2017). Some case studies, construction aspects and quality control guidance will also be provided. The course is aimed at providing:

• A comprehensive understanding of the issues involved in FRP retrofitting of concrete structures

• An overview of the design procedures for strengthening of concrete structures according to the AS5100.8 (2017) using FRP.

• Worked examples on strengthening of reinforced concrete beams in flexure and shear and columns for axial loads using FRP.

Case studies, construction aspects and quality control guidance will also be provided.

1.30 - 3.00 Session 3 - SHEAR STRENGTHENING OF CONCRETE STRUCTURES ACCORDING TO AS5100 • The new shear model in AS5100 • Strengthening beams in shear using FRP systems • Possible failure modes of strengthened beams • Effect of strengthening scheme • Strengthening for ultimate limit state • Worked examples


PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed) 3.15 - 5.00 Session 4

- STRENGTHENING OF CONCRETE COLUMNS ACCORDING TO AS5100 AND FRP ANCHORAGE SYSTEMS 9.00 - 11.00 Session 1

- APPLICATION OF FRP TECHNOLOGY IN STRUCTURES • Infrastructure crisis • Damage and Deterioration Issues in Concrete and Steel

Reinforcement • Conventional Strengthening & Repair Techniques • Introduction into strengthening of RC structures using FRP • Types of FRP strengthening systems • Materials and properties of FRP strengthening systems • Strengthening limits • Quality control and assurance • Structural fire endurance • Environmental reduction factors


• The influence of confinement of concrete compressive strength • Confinement strength models • Strengthening rectangular and circular sections using FRP • Axial moment interaction • Worked examples • FRP anchorage systems for flexure and shear strengthening


11.15 - 1.00 Session 2 - FLEXURE STRENGTHENING OF CONCRETE STRUCTURES ACCORDING TO AS5100

• Strengthening for ultimate limit state • Failure modes and overview into FRP premature debonding • Serviceability considerations • Worked examples


DR. RIADH AL-MAHAIDI PhD MS(Str) BE Civil(Hons) • Professor of Structural Engineering and Director of the Smart

Structures Laboratory at Swinburne University of Technology. • Research and practice interests in the area of structural

strength assessment and retrofitting using advanced composite materials.

DR. ROBIN KALFAT PhD(Str) BE Civil(Hons) • Senior Lecturer in Civil and Construction Engineering at

Swinburne University of Technology. • He has 15 years of industry experience in the area of

strengthening of concrete structures using fibre reinforced composites.


• Email

[email protected]




Live streamed via



FRP STRUCTURAL DESIGN WORKSHOPStrengthening of concrete structures using fibre reinforced polymers (FRP) according to AS5100

NEW COURSE



METALLURGY MATERIALS WORKSHOP

WORKSHOP SUMMARY The construction industry in Australia today is going through major changes especially in light of imported building products. Engineers are therefore not only having to design structures but also now be aware of the potential variance in material properties of the construction materials used in their design. In particular, structural steels being imported into the country often vary in their chemistry and material properties compared to Australian steels. This workshop will allow both structural and mechanical engineers to fully understand the chemical, physical and structural properties of steels and the alloys that are included within them. The course will then address the potential failure of these metals with regards to fatigue, fracture and corrosion. Tutorial exercises (and solutions) will follow at the end of each session.

1.30 - 3.00 Session 3 - FRACTURE AND FATIGUE FAILURE OF METALS

• Elastic vs Plastic failure of steel with respect to deformation • Fracture mechanics of metals (and how to measure it experimentally) • Importance and determination of crack widths • Interpretation of fatigue strength vs no of cycles graphs • Methods of improving fatigue life in structures • Determination of steel failure (ie yielding vs fracture) • Tell tales signs of impending failure • Tutorial


PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed) 9.00 - 11.00 Session 1 - IRON, CAST IRON AND STEEL PROPERTIES

3.15 - 5.00 Session 4 - CORROSION OF METALS

• Stages of the production of iron and cast iron and how these differ from the production of steel

• Atomic and crystalline structure of metals (including the effects of atom position and bonding), BCC vs FCC

• Typical stress strain curves for various steel types • Elastic Modulus, Yield Strength, Strain Hardening, Ultimate Tensile

strength, Ductility, Necking and Fracture. • Tutorial


• Ten corrosion mechanisms • Anode vs cathode reactions • Electron transfer processes, Faraday Law concepts • Formation of ferrous hydroxides to ferrous oxide transformation • Galvanic vs Cathodic protection of steels • Passivation of steel • Life expectancy of ferrous alloyed steels (marine vs non marine

environments) • Tutorial

Certificate of Attendances will be emailed 11.15 - 1.00 Session 2 - PHASE DIAGRAMS, SOLIDIFICATIONS AND DEFECTS AND TEMPERATURE TREATMENTS

• Phases that constitute steel (eg austenite, ferrite, cementite, bainite, martensite) and the different types of microstructure components that can be present (pearlite, bainite)

• Types and effects of various alloys (eg Mn, Ni, Cr V, Co, Si) • Effect of temperature treatments eg Annealing, Quenching and

Tempering (which achieve specific types of phases and microstructure constituents such as martensite, bainite etc) which produce steels such as Q & T steels (eg Bisalloy) or outer core tempered reinforcing bars (N bars vs mesh).

• The properties and effects of defects, vacancies, grain boundaries, interstitial and substitutional atoms.

• Tutorial


DR. GWÉNAËLLE PROUST BE(Fr) ME(USA) PhD(USA) • Senior Lecturer, Faculty of Engineering and IT, at the University

of Sydney. • Gwénaëlle has written numerous journal articles on various

metals and the mechanics of materials.


• Mobile 0413 998 031 • Email

[email protected]





Live streamed via



PROCESS PIPING (PRESSURE) DESIGN WORKSHOP

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WORKSHOP SUMMARY The aim of this two day workshop is to provide participants with an understanding of the principles and minimum requirements of ASME B31.3, Pressure Piping Code.

This course is designed for mechanical, structural and civil engineers who wish to understand the principles involved in Process Piping.

This workshop will cover the minimum requirements for “Design, Calculations, Material Selection, Fabrication-Assembly-Erection and Examination-Inspection-Testing” in accordance with the most globally recognised reference, ASME B31.3 Process Piping Code. All sessions provide worked examples, tutorial exercises and solutions.

DAY TWO 9.00 - 11.00 Session 5 - DETAILED DESIGN III • Design for Sustained Bending

Moments, Torsional moments, and for Sustained Longitudinal Forces

• Cyclic Loading vs Stresses • Tutorial

11.00 - 11.15 Morning Tea

11.15 - 1.00 Session 6 - FABRICATION

DAY ONE (8.30 - 9.00 Zoom invite link will be emailed) • End Preparation • Typical Butt Weld requirements • Typical Fillet Weld requirements • Preheating Requirements • Post Weld Heat Treatment Requirements (PWHT) • Minimum Holding Times at Temperature for Control Thickness • Exemptions • Tutorial


9.00 - 11.00 Session 1 - MATERIALS • Scope and Definitions • Relevant Codes and Standards • Materials used in Process Piping • Ferrous vs Non Ferrous materials • Steel requirements (eg carbon

content, austenitic s/s) • Minimum wall thicknesses • Temperature limitations • Impact requirements • Tutorial


1.30 - 3.00 Session 7 - ASSEMBLY AND ERECTION

• Alignment Requirements • Bolt Length and Nut requirements • Bolt Torque requirements • Gasket requirements • Tutorial


11.15 - 1.00 Session 2 - DESIGN BASICS • Design Temperatures (Maximum and Minimum) • Allowable stresses in Tension • Pipe Ratings • Correlation of Fitting vs Class • Requirements for Bolting and Welding • Tutorial


3.15 - 5.00 Session 8 - INSPECTION, EXAMINATION, TESTING

• Visual vs Radiographic examination and testing • Checking for Undercuts, Lack of Fusion, Incomplete Penetration • Slag Inclusion checks including Surface Porosity • Hydrostatic Leak testing and Sensitive Leak testing • Low Temperature, Pressure and Fluid testing • Crack issues


1.30 - 3.00 Session 3 - DETAILED DESIGN I

• Elastic Limit vs Offset vs Proportional Limit • Yield Strengths for Ferrous and Non Ferrous piping • Weld Joint Quality Factor • Forged Fittings, Socket Welding and Threaded • Threaded Joints vs Corrosion • Factory Made Wrought Butt-welded Fittings • Branch Connections • Tutorial


3.15 - 5.00 Session 4 - DETAILED DESIGN II

• Pressure Design of Components • Pipe Thickness vs Allowable Stress vs Joint Efficiency • Design of Elbows • Design of Miter Bends • Design of Blanks

AMIR ESMAEILI FIEAust CPEng NER APECIntPE(Aus) RPEQ ASME B31.3 IRG • Over 17 years of experience in the Oil & Gas Industry. • NER Oil & Gas Pipeline and Mechanical • Worked in Oil & Gas Refineries, Petrochemical Plants, Large size - High Pressure

Transportation Pipelines all located in the Persian Gulf.



• Email

[email protected]

COURSE COST • 2 day course – $1,570 pp


Live streamed via

WORKSHOP SUMMARY This course addresses the theory behind the processes of steel corrosion, concrete cracking and masonry failure. It then focuses on the preparation of concrete and steel surfaces (both reinforcement and structural steel) before protection systems are applied. Each session will be followed by a tutorial exercise (and solutions) to ensure participants have fully understood the concepts presented in this workshop. The final session comprises three practical presentations on the products that are available in the marketplace and how they provide the necessary protection systems to the building and construction industry.

11.00 – 1.00 Session 2 (Paul Uno) - SURFACE PREPARATION - TESTING METHODS & EVALUATION CRITERIA Surface Preparation • Peening • Pressure Water Blasting • Scabbling • Scarifying • Shot Blasting • Slag (Sand) Blasting – Concrete and Steel • Concrete Surface Profile (CSP1 to CSP9) • TUTORIAL

Testing Methods & Evaluation Criteria • Concrete Core Testing • Concrete Resistivity • Corrosion Rates and Mass Loss (inc Faraday’s Law) • Cover Meters (for Steel) • Film Thickness Testing –Dry (DFT) and Wet (DFT) • Half Cell Mapping • Klopfer CO2 Diffusion Tests • Langelier Saturation Index and Ryznar Stability Index • Linear Polarization • Moisture Meters • Petrographic Analysis • Phenolphthalein tests • Pull off Tension Adhesion Test (using an Elcometer) • Schmidt Hammer (Rebound Impact) • Slip Resistance (Pendulum test) • Swimming Pools vs Lime Scaling vs Pipe Corrosion • Water Balance Tests (eg Pools) • TUTORIAL


PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed) 9.00 - 11.00 Session 1 (Paul Uno) - DURABILITY THEORY • ACI Aggressive Chemicals for Concrete List • Alkali Aggregate Reaction • Australian Standards Durability Requirements eg AS3600,

AS2870, AS2159, AS4100 • Cement and Epoxy Exothermic Reactions • Cement Types GP vs GB vs HE vs SR vs CAC’s • Coating Breathability vs Vapour Diffusion vs Blistering • Concrete Abrasion (eg Forklifts vs Trucks) • Concrete Carbonation (to AS4548.5) and Klopfer Criteria • Concrete Chloride Diffusion (inc. Ficks 2nd Law of Diffusion) • Concrete Conductivity and Resistivity values • Concrete Cracking (eg Early Age/Plastic, Settlement,

Shrinkage, Thermal, Chemical, AAR) • Concrete Porosity vs Permeability • Concrete Sulphate Attack • Corrosion of Steel (10 Main Classes) eg Pitting, Crevice,

Uniform, Stress, Embrittlement etc • Dusting vs Surface Hardeners (eg Fluoro-Silicates) • Fire Damage • Iron Pyrite Aggregate in Concrete and Masonry • Magnesite Floor Topping Issues • Masonry Rising Damp vs Salt Crystallisation • Plastic Shrinkage Cracking, APPS and Environmental Factors • Supplementary Cementitious Materials for Repair (eg Flyash,

Slag and Silica Fume) • Water Corporation - Six Classes of Steel Rebar corrosion. • TUTORIAL



PAUL UNO BE MBdgSc MIE(Aust) CPEng NER RPEQ APEC Engineer IntPE(Aus) • Over 40 years of experience in engineering design and construction and in the area of repair materials. • Engaged by legal and insurance companies to assess damaged structures and various repair materials. • Part-time Senior Lecturer – UNSW & The University of Sydney. • Chairman of the Australian Standards committee BD-066 for the Tilt-Up & Precast (Prefabricated)

Concrete Standard AS3850.

Live streamed via


REPAIR & PROTECTION WORKSHOP -

1.30 - 3.15 Session 3 (Paul Uno) - PROTECTION MATERIALS & REPAIR METHODS

3.30 - 4.15 Session 4 (Stephen Waite – SW Consult) - CONSULTING ENGINEER’S REPAIR EXPERIENCES

• Bentonite (waterproofing) Clays • Corrosion Inhibitors (eg Nitrites) • Crack Injection • Crystalline Technology • Curing Agents (and removal) • Epoxies (Part A) and Diamines (Part B - Hardener) • FRP sheeting • Galvanising to AS4680 • Grouts Non-Shrink (Type A vs C vs Z) • Inorganic Zinc Silicates for structural steels • Paints –Water vs Oil Based • Polyurethane Polymers • Self-Levelling compounds (using CAC’s) • Shrinkage Reducing Admixtures (SRA’s) • Silanes vs Siloxanes • Stainless Steel (304 vs 316 vs Duplex) • Weathering Steels (ie Structural Steels) • Zinc Coatings (Applied Coatings vs Galvanised) • TUTORIAL


• This session is presented by a consulting engineer who has specialised in the repair of concrete structures over 20 years.

• Stephen Waite will share his valuable experiences from the many projects he has been involved with around Australia.

• He will address case studies and outline the pros and cons of the various approaches to the remediation of these structures.

4.15 - 5.00 Session 5 (Nader Zaki – Helifix) - MASONRY REPAIR USING STAINLESS STEEL REINFORCING • Systems available for repair and retrofit strengthening of clay,

stone and concrete masonry structures. • Many problems have occurred over the years from rusting

cavity wall ties, cracking of masonry, separation of connecting walls, reduced flexural or shear strength, brick growth, foundation movement and footing failure.

• Methods (eg. HELIFIX System) and tools available to reinstate masonry walls back to a proper composite system and improve strength, ductility and performance of existing masonry structures that have been compromised.

Certificate of Attendance & Feedback sheets

STEPHEN WAITE MSc (Str. Eng) BSC(Hons) RPEQ • Director - Structural Waterproof Consulting (SW Consult) • Structural Engineer specialising in remediation, structural

repairs and rectification including waterproofing of existing structures (mainly high-rise structures).

FURTHER INFORMATION • Office (02) 9899 7447 • Mobile 0413 998 031 • Email [email protected]



NADER ZAKI BEng (Civil) MIE • Business Unit Manager - Provides technical advice and

assistance for Helifix Australia and associated entities. • Manages quality of product & service delivery, working

closely with engineers, builders and project managers.


CONCRETE, STEEL & MASONRY STRUCTURES

WORKSHOP SUMMARY This course is aimed at civil and structural engineers in Australia and New Zealand who wish to design residential slabs and footings to either the current Australian Standard AS2870-2011 or NZ B1 Building Code, Structure NZ (inc Amdt 19) which is referenced in NZS 3604 Section 17, Expansive soils, or, by Basic Structural Engineering Principles. This workshop will cover relevant topics relating to slabs and footings over the two- day period and will also address FINE (GEO5) software.

3.15 - 5.00 Session 4 - CONCRETE MIX DESIGN AND ON-SITE CONCRETE PLACEMENT ISSUES (eg Cracking) • Materials used in concrete mixes for house slabs and footings (including flyash

blends and market branding eg builders cement) • Effect of Sulphates on Concrete used in domestic construction • Polythene (polyethylene) VPM and DPM underlay requirements (as per AS4347.6) • Water to cement ratios (including effects of slumps 80mm, 100mm and above) • Typical Concrete Mix designs used in residential concrete. • Types of cracking common to residential slabs (eg plastic shrinkage cracking, plastic

settlement cracking and longer-term drying shrinkage) and use of trimmer bars • Minimise cracking on slabs by attention to weather conditions (temperature,

humidity, wind speed) to quantify the potential for plastic shrinkage cracking • Admixtures, evaporative retarders & curing compounds (assist cracking minimization) • Non-structural crack issues (crazing, dusting, durability, corrosion control points) • Proper joint saw cutting techniques (where required) • Effects of deteriorated wall ties and omission of slip joint material • Effects of using low ductility mesh in suspended concrete slabs • Relationship between concrete slab crack size and termite entry DAY 2

DAY 1 (8.30 - 9.00 Zoom invite link will be emailed) 9.00 - 11.00 Session 1 - SOIL PROPERTIES AND SOIL SUCTION • Clay mineralogy and swelling potential (Kaolinites, Illites, Montmorillonites) • Clay cracking potential eg 2:1 vs 1:1 clay types • Expansive clays distribution map for Australia • Soil Salinity vs Soil Sodicity and its effect on Soil Swelling vs Concrete Degradation • Soil Suction parameters (Matric vs Osmotic suction) vs Total Soil suction (pF scale) • Effects of Sulphates in soil • Soil Electrical Conductivity Extract (Ece in dS/m) vs Osmotic Suction values (kPa) • Cation Exchange Capacity (CEC) & Activity ratio (AR) for various clays • Thornthwaite Moisture Index (TMI) and Soil Suction Change Design Depth (Hs) • Atterberg Limit Tests vs Shrink vs Swell Tests (as per AS1289) • Correlation regression: Shrink-Swell Tests vs Atterberg limits (eg LL, PL, PI and LS) • Shrink-Swell Index (Iss) Soil properties • Soil Classifications (S, M, H1, H2, E) • Site Classifications (including P sites) • Tutorial 1 (Soil Properties)


9.00 - 11.00 Session 5 - SOIL CAPACITY, APPLIED LOADS, ULTIMATE vs ALLOWABLE BEARING CAPACITY • Soil Cohesion (Cu) and (C’) vs Soil Angle of Internal Friction (φ) • Drained vs Undrained Soils • Soil Test Correlations DCP vs SPT vs ys • Typical dead loads on domestic slabs and footings (eg roof tiles, studs, frames) • General Applied Loads (and Pressures) as per AS/NZS 1170.1 • Soil Bearing Capacity - Allowable vs Ultimate • Basic Terzaghi (and Vesic) formulas to determine ultimate bearing capacities for

rectangular, strip and circular footings. • Tutorial (in NCC (Aust) & NZS 3604 Section 17, Expansive Soils, Building Code B1).


11.15 - 1.00 Session 2 - SITE CLASSIFICATION AND SWELLING POTENTIAL (including effect of Trees and Cut/Fill) • Determination of Site Classifications (including P sites), Soil Suction Change Design

Depth (Hs), and Characteristic Surface Movement (ys) • Calculating the surface movement ys using soil shrinkage index values, suction

values, soil layer thicknesses to then achieve a site classification (eg M, H1, H2, E) • Determine Surface Movement & Suction Design Depth due to Trees ie (yt) and (Ht) • Design suction change profiles • Determination of Crack Depths • Effect of Cut and Fill • Effect of Trees on ys and Hs • Tutorial Exercise 1 (Soil suction only) • Tutorial Exercise 2 (Soil suction including effect of trees) • Tutorial Exercise 3 (Soil suction including cut and fill effects)


11.15 - 1.00 Session 6 - SLAB DESIGN: Standard (Deemed to Comply) Method #3.0- AS2870 vs Chart 4.1

• Chart 4.1 in Section 4.0 of AS2870 (& its derivation) determine the footing beam depth • Effective Slab Widths applicable to slabs in domestic construction • Uncracked vs Cracked Second Moment of Area calculations (ie MOI) • Beam depth, spacing and minimum reinforcement, trimmer bars • Suspended slab design in domestic construction • Tutorial Exercise

1.00 - 1.30 Lunch Break 1.30 - 3.00 Session 3

- DOMESTIC CONSTRUCTION CONSIDERATIONS (as per AS2870)

1.30 - 3.00 Session 7 - ENGINEERED DESIGN (#4.0 AS2870) plus Steel Screw & Bored Concrete Piers Design

• Clad frame vs articulated masonry veneer vs masonry veneer, vs articulated masonry full vs full masonry (double brick), and their appropriate footing systems.

• Requirements of articulation in masonry walls (as per CCAA TN61) • Footing systems: raft slab, footing slab (SOG), waffle slab, stiffened slab, strip footing • Compaction of fill (rolled, controlled, sand, non-sand) in accordance with AS2870 • Drainage issues eg leaking pipes, poor drainage, pavement slope • Incorrect usage of waffle pod system & potential litigation • Properties of polystyrene pods including proper disposal • Pros and cons of using a waffle pod slab system • Requirements of Steel Reinforcement • Other void systems (eg domes) • Measures to provide effective site drainage • Tutorial Exercise


• Centre Heave (sometimes referred to as Hogging or as Edge Drop) • Edge Heave (sometimes referred to as Sagging or as Edge Lift) • Structural Design of Concrete Piers/Piles • Structural Design of Steel Screw Piers for domestic beam and slab construction

(Individual Bearing method vs Cylindrical Shear method) and accounting for potential punching shear failure according to IPENZ Note 28 document etc

• Winkler method vs Walsh Method vs Mitchell Method • Use of FINE (GEO5) Beams and Slabs on Elastic Foundations software • Tutorial Exercise

3.00 - 3.15 Afternoon Break 3.15 - 5.00 Session 8 - HOUSE SLAB DESIGN EXAMPLES • Estimation of Wall loads, Roof loads and Floor loads (as per AS1170.1 and AS2870) • Structural design of various concrete slabs using house plans from start to finish

using both Stiffened Raft (conventional method) and Waffle Pod (Rib Raft) methods for various soil types eg M, H, E (incl. effect of trees) in various combinations, eg: o Single Storey home - Rectangular house plan – SOG Design o Single Storey home -Non-Rectangular house plan – Slab on Ground (SOG) Design o Double Storey home -Rectangular house slab plan + Suspended concrete slab


PAUL UNO BE MBdgSc MIE(Aus) CPEng NER RPEQ APEC Engineer IntPE(Aus)

• Over 40 years’ experience in the design & construction industry. • Part-time Senior Lecturer – UNSW and University of Sydney. • Inspected many concrete slabs and footings as well as written

numerous reports on why slabs have failed.

Recommended Text:

Reinforced Concrete: The Designers Handbook (2015 Revised Edition) Beletich, Hymas, Reid and Uno

Live streamed via

Download FINE GEO5 demo version www.etia.net.au/geo5-demo-version

COURSE COST • 2 day course – $1,590 pp

FURTHER INFORMATION • Registration form (back of catalogue) • Visit our website www.etia.net.au • Office (02) 9899 7447 • Mobile 0413 998 031 • Email [email protected]


RESIDENTIAL SLABS & FOOTINGS DESIGN WORKSHOP


WORKSHOP SUMMARY This workshop is designed to introduce vibration and fatigue analysis to engineers. The fundamental concepts of vibration will be covered including modal (natural frequency) analysis, response spectrum analysis and vibration analysis of machinery. The second half of the workshop will focus on fatigue. Basic concepts will be introduced followed by practical lessons on the application of the most commonly used fatigue design standards – AS 4100 and BS 7608. The workshop will also introduce more advanced concepts such as variable amplitude loading, cycle counting and non-proportional loading.

1.30 - 3.00 Session 3 - INTRODUCTION TO FATIGUE • Introduction to Fatigue • Crack Initiation • Factors Influencing Fatigue • Fatigue Life Models • Stress-life approach – Unwelded Material • Mean Stress Effects – Unwelded Material • Variable Amplitude Loading • Fatigue Design to Standards • Fatigue Design to AS 4100 • Tutorial questions with solutions provided


3.15 - 5.00 Session 4 - FATIGUE DESIGN TO STANDARDS • Fatigue Design to AS 4100 (continued) • Fatigue Design to BS 7608 • BS 7608 - Fatigue Loading • BS 7608 – Environmental Considerations • BS 7608 – Factors on Fatigue Life • BS 7608 – Classification of Details • BS 7608 – Stress Calculations • BS 7608 – Allowable Fatigue Stresses • Tutorial questions with solutions provided


PROGRAMME (8.30 - 9.00 Zoom invite link will be emailed) 9.00 - 11.00 Session 1 - INTRODUCTION TO VIBRATION • Mechanisms and Structures • Rigid Body Motion and Degrees of Freedom • Discrete and Distributed Systems • Undamped Free Vibration of Particles • Damped Free Vibration of Particles • Modes of Vibration • Tutorial questions with solutions provided


11.15 - 1.00 Session 2 - INTRODUCTION TO VIBRATION ANALYSIS

• Frequency vs Time Response Analysis • Resonance • Vibration Acceptance Criteria • Random Vibration • Response Spectrum Analysis • Vibration Analysis


MATT RUDAS MIEAust NER RPEQ CPEng

• Chartered mechanical engineer with over 25 years of experience • Owner principal at Mechsafe Engineering • Specialist FEA and BEA analyst of stress, fatigue and fatigue crack

growth in structures and heavy machinery



• Mobile 0413 998 031 • Email

[email protected]



Live streamed via



VIBRATION & FATIGUE ENGINEERING WORKSHOP

NEW COURSE

ENGINEERING TRAINING INSTITUTE AUSTRALIA PO Box 913 Baulkham Hills NSW 1755 Ph: (02) 9899 7447 Mob: 0413 998 031

Email: [email protected] Website: www.etia.net.au A.B.N. 27 830 322 080

REGISTRATION FORM

1 ACCOUNTING & MANAGEMENT FOR ENGINEERS COURSE (1 day course - $670 pp)

Attendee Name/s Amount

• LIVE STREAM – Tue 1 September 2020 $

2 CEMENT & CONCRETE ENGINEERING TECHNOLOGY WORKSHOP (1 day course - $880 pp)


• LIVE STREAM – Wed 26 August 2020 $

3 CONCRETE PIPES & PIPELINE DESIGN WORKSHOP (1 day course - $690 pp)


• LIVE STREAM – Thu 10 September 2020 $

4 FINITE ELEMENT ANALYSIS WORKSHOP (1 day course - $785 pp)



5 FORENSIC ENGINEERING WORKSHOP (1 day course - $795 pp)


• LIVE STREAM – Tue 25 August 2020 $

6 FRP STRUCTURAL DESIGN WORKSHOP (1 day course - $870 pp)



7 METALLURGY MATERIALS WORKSHOP (1 day course - $735 pp)



8 PROCESS PIPING (PRESSURE) DESIGN WORKSHOP (2 day course - $1,570 pp)


• LIVE STREAM–Tue 29+Wed 30 September 2020 $

9 REPAIR & PROTECTION WORKSHOP (1 day course - $790 pp)



10 RESIDENTIAL SLABS & FOOTINGS DESIGN WORKSHOP (2 day course - $1,590 pp)


• LIVE STREAM –Tue 18 + Wed 19 August 2020 $

RECOMMENDED TEXT: Reinforced Concrete: The Designers Handbook (2015 Revised Edition) - $170 QTY: $

11 VIBRATION & FATIGUE ENGINEERING WORKSHOP (1 day course - $805 pp)



TOTAL COST $ (GST included)

NB: Cancellations made more than 5 working days prior to a course will incur a 20% processing fee of the full registration amount.

Cancellations made 5 working days or less will incur forfeiture of the full registration fee.

EA AUGUST 2020

ENGINEERING TRAINING INSTITUTE AUSTRALIA PO Box 913 Baulkham Hills NSW 1755 Ph: (02) 9899 7447 Mob: 0413 998 031

Email: [email protected] Website: www.etia.net.au A.B.N. 27 830 322 080

HOW TO REGISTER Option 1: Register online www.etia.net.au (Receive immediate tax invoice receipt & confirmation) Option 2: Fill in this form and email to [email protected] (Allow 3 – 5 business days for tax invoice receipt & confirmation)

VISA* MASTERCARD* AMEX*(additional 1.3% surcharge) * All credit cards are charged a merchant fee of $0.50 per course

CVV#

Cardholder’s Name____________________________________ Expiry Date_____ /_____ Signature__________________________

Person Handling Payment__________________________________ Email________________________________________________

Company _________________________________________________________ Phone (_____)__________________________

Attendee #1 Email __________________________________________________________________________________________

Attendee #2 Email __________________________________________________________________________________________

Postal Address _____________________________________________________________________________________________

Suburb _________________________________________________________ State ___________ Postcode _____________

LIVE STREAMING DETAILS 1. Registrations must be received at least three (3) working days before the live streamed workshop, to allow for

course notes to be express posted. Course notes are only provided as a hard copy. Any registrations received after

this period will result in a later delivery of course notes.

2. Only registered attendees are permitted to view the online live stream.

3. Online participants MUST have their webcam on during the presentation. Failure to do so will result in the

attendee being denied access to the live stream.

4. Please ensure the attendee provides their own personal/work email upon registration.

5. Attendees will be emailed a Zoom link between 8:30am - 9:00am on the day of the course, to join the live stream.

HOW DID YOU FIND OUT ABOUT US? (Please circle)

1) Engineers Australia magazine 2) ETIA website 3) Brochure in mail 4) Sponsor 5) Email 6) Training manager 7) Google search 8) Other _______________________________

NB: Cancellations made more than 5 working days prior to a course will incur a 20% processing fee of the full registration amount. Cancellations made 5 working days or less will incur forfeiture of the full registration fee.

EA AUGUST 2020

FINE SOFTWARE (GEO5) available from ETIA website link

https://www.etia.net.au/store

Engineering Training Institute Australia Sponsors 2020 AFS Formwork www.afsformwork.com.au Ancon Building Products www.ancon.com.au BarChip Inc. www.barchip.com Concrete Masonry Association of Australia www.cmaa.com.au Connolly www.connollykeyjoint.com CSR Hebel www.hebel.com.au Danley www.danley.com.au Engineering Accountants & Advisors www.unoaccounting.com.au FINE Software www.etia.net.au/store Granor Rubber & Engineering www.granor.com.au Helifix www.helifix.com.au Katana Foundations www.katanafoundations.com.au RamsetReid www.ramsetreid.com Think Brick Australia www.thinkbrick.com.au WoodSolutions www.woodsolutions.com.au

DOWNLOAD FREE DEMO

VERSION

FREE DEMO Scan the QR Code to download the demo

FINE SOFTWARE (GEO5) available from ETIA website link

https://www.etia.net.au/store

Engineering Training Institute Australia Sponsors 2020 AFS Formwork www.afsformwork.com.au Ancon Building Products www.ancon.com.au BarChip Inc. www.barchip.com Concrete Masonry Association of Australia www.cmaa.com.au Connolly www.connollykeyjoint.com CSR Hebel www.hebel.com.au Danley www.danley.com.au Engineering Accountants & Advisors www.unoaccounting.com.au FINE Software www.etia.net.au/store Granor Rubber & Engineering www.granor.com.au Helifix www.helifix.com.au Katana Foundations www.katanafoundations.com.au PAEC Consulting Services www.paec.com.au RamsetReid www.ramsetreid.com Think Brick Australia www.thinkbrick.com.au WoodSolutions www.woodsolutions.com.au

DOWNLOAD FREE DEMO

VERSION

FREE DEMO Scan the QR Code to download the demo

engineering training institute australia · 1.00 - 1.30 lunch break calculators required paul uno...

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