AS 4324.1 Brownfield Bulk Handling Assets: Engineering Mobile Equipment for Today’s Mine Sites

AS 4324.1 Bulk Handling Equipment | Brownfield Stacker & Reclaimer Engineering

Mobile equipment for the continuous handling of bulk materials—such as stackers, reclaimers, and ship loaders—forms the backbone of Australia’s mining and export infrastructure. Many of these assets operate continuously in demanding environments, often well beyond their original design life.

Australian Standard AS 4324.1 provides essential guidance for the design and safe operation of this class of equipment. However, on many Australian mine sites, the practical application of the standard is misunderstood or only partially implemented, particularly when dealing with legacy machines and brownfield upgrades.

For asset owners and engineering managers, the challenge is rarely about greenfield compliance. It is about managing risk, extending asset life, and implementing upgrades without unplanned downtime.

Ship loader and bulk cargo vessel with GPS monitoring units and sensor overlays illustrating controlled loading zones and engineering oversight under AS 4324.1

Understanding AS 4324.1 in a Brownfield Context

AS 4324.1 addresses mobile equipment used for continuous bulk handling, including:

Yard stackers and reclaimers
Bucket wheel reclaimers
Slewing and travelling machines
Ship loaders at export terminals

While the standard establishes a strong baseline for design and safety, many operating machines:

Pre-date the current revision of the standard
Have undergone multiple undocumented modifications
Operate under loading conditions that differ from original assumptions

In these situations, engineering judgement is required. Compliance becomes less about box-ticking and more about demonstrating that risks are understood, controlled, and managed over the asset lifecycle.

Common Challenges on Operating Mine Sites

Across coal handling plants, iron ore operations, and port facilities, several recurring issues emerge:

1. Incomplete or Outdated As-Built Information

Accurate geometry, slew limits, clearances, and structural interfaces are often unknown. This creates risk during upgrades and maintenance planning.

2. Fatigue and Structural Degradation

Large mobile machines experience cyclic loading across slewing, luffing, and travel motions. Fatigue cracking and unexpected failures require ongoing monitoring, not one-off assessments.

3. Access, Guarding, and Maintenance Compliance

Requirements evolve over time. Older machines may not meet current expectations for access systems, guarding, or safe maintenance practices.

4. Downtime Sensitivity

Stackers, reclaimers, and ship loaders are often production-critical assets. Upgrade windows are limited, and poor fit-up or rework can have significant commercial consequences.

Technology Supporting Modern Risk Management

While AS 4324.1 remains the foundation, modern technology allows asset owners to manage risk more effectively—particularly on brownfield equipment.

GPS Positioning and Controlled Operating Zones

Where GPS positioning is enabled, defined operating zones can be established to:

Prevent interaction with stockpiles during rapid translation
Automatically reduce slew or travel speed in high-risk zones
Limit impact loads on critical components such as slew rings and fluffing gears

These systems are primarily productivity-driven, but they also reduce the likelihood of high-energy impacts that contribute to mechanical damage.

LiDAR Scanning as an Emerging Risk Layer

LiDAR scanning is not a replacement for traditional controls, and it is still evolving in this application. However, it can provide:

Accurate spatial awareness of surrounding structures
Verification of clearances and exclusion envelopes
A secondary risk-management layer supporting operator decision-making

When combined with engineering-led interpretation, LiDAR contributes to a layered risk approach rather than acting as a standalone safety system.

Condition Monitoring and Real Load Understanding

Accelerometers installed across a range of frequencies can deliver valuable insight into:

Actual operating loads
Dynamic response during slewing, reclaiming, and travel
Early indicators of fatigue-related issues

This data supports more informed maintenance decisions and provides evidence of how a machine is truly being used—often revealing load cases not considered in original designs.

Engineering-Led Compliance and Asset Life Extension

For brownfield assets, compliance with AS 4324.1 is best approached as a continuous engineering process, not a single milestone. This includes:

Accurate reality capture and digital models
Verification of clearances, interfaces, and structural geometry
Informed upgrade design that fits the first time
Risk-based decision-making supported by real operating data

This approach helps asset owners extend the life of critical machines while managing risk, performance, and availability.

How Hamilton By Design Supports Bulk Handling Assets

Hamilton By Design works with asset owners and engineering teams to support:

Brownfield upgrades of stackers, reclaimers, and ship loaders
Engineering-grade LiDAR scanning and as-built documentation
Fit-for-purpose mechanical design for modifications and life-extension
Independent engineering insight across OEM and site interfaces

Our focus is on engineering clarity, practical risk reduction, and minimising disruption to operations.

Talk to an Engineer About Your Asset

If you are planning a brownfield upgrade, life-extension, or risk review of mobile bulk-handling equipment, talk to an engineer at Hamilton By Design about how accurate data and practical engineering can support your next decision.

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Mining Engineering Services Australia

25 October 202514 January 2026

Integrating 3D Scanning and Mechanical Design for Safer, Faster Upgrades in Coal Wash Plants

Precision Without the Guesswork

Upgrading or maintaining a coal wash plant has always been a challenge — tight shutdown windows, complex layouts, and the need for perfect fit-ups between new and existing components. Traditional measurement methods, like tape measures and manual sketches, are often impossible in restricted or hazardous areas.

That’s where 3D scanning and mechanical engineering come together. At Hamilton By Design, we combine precision laser scanning, intelligent 3D modelling, and practical mechanical design to deliver risk-free upgrades — ensuring every component fits right the first time.

Infographic showing how 3D scanning and 3D modelling feed into mechanical design for safer, faster upgrades at a coal wash plant, with icons representing scanning, modelling, and engineering drawings

When Accuracy Matters Most

Coal wash plants are intricate systems. From cyclones, screens, and diverter chutes to pumps, piping, and structures, every part interacts under tight tolerances. A small misalignment can lead to vibration, spillage, or shutdown delays.

Our 3D scanning process captures millions of spatial data points, creating a detailed digital twin of the existing plant. This allows us to model upgrades, design replacement components, and simulate fit-up — all before fabrication begins.

In many cases, scanning replaces the need to physically measure equipment. For example, in confined or high-risk spaces where a tape measure simply can’t reach, scanning provides complete, line-of-sight geometry with millimetre accuracy.

Recently, our team scanned a diverter chute that had been incorrectly installed. The resulting model revealed that the chute had been fitted in the wrong orientation — explaining why it wasn’t sealing properly. This insight helped our client avoid further downtime and costly rework.

Combining Engineering Experience with Digital Precision

Hamilton By Design provides a full suite of mechanical engineering services tailored to the mining industry, including:

3D Scanning & Point Cloud Capture – detailed mapping of existing equipment and structures
3D Modelling & Reverse Engineering – accurate, editable digital models
Mechanical Design & Structural Replacement – like-for-like component upgrades
Piping Routes & Spool Fabrication – optimised pipe design and layout
Fabrication & Component Drawings – compliant with Australian Standards and client templates

Our engineers work across SolidWorks, AutoCAD Plant 3D, Revit, and 3D Experience platforms — integrating point cloud data directly into the design workflow. This means fewer site visits, fewer surprises, and significantly less rework once fabrication begins.

From Drawings to Digital Models

We’ve evolved beyond traditional 2D general arrangement drawings. Instead, we provide interactive 3D models and e-drawings that allow clients, fabricators, and site teams to visualise how upgrades will fit within the plant.

Our reverse cloud modelling process inserts 3D designs directly into the scanned environment. This enables engineers and site teams to measure potential interferences, check clearances, and validate installation methods — long before shutdowns begin.

Illustrated workflow showing how 2D GA drawings and scanned environments are turned into 3D digital models through reverse cloud modelling and eDrawings, demonstrating confidence in fabrication fit for mining and industrial equipment.

The result = Confidence.
Every pipe spool, chute, and bracket is designed to fit — without compromise.

Supporting Contractors and Plant Operators

We partner with:

Mining companies operating coal wash plants
Fabricators and contractors supplying mining equipment
Maintenance providers planning plant shutdowns

Their biggest challenge is finding people who design for fit and function — not just form. Not all CAD or point cloud software is equal, and not every designer understands the realities of on-site installation. That’s where Hamilton By Design stands apart.

We bring hands-on mechanical trade experience, engineering design expertise, and digital technology together — helping your team deliver upgrades that work, first time.

Built to Australian Standards

All design and drawing deliverables are completed in accordance with Australian Standards, ensuring compliance, safety, and interoperability with existing documentation.

We can also supply fabrication drawings on client-specific templates, maintaining intellectual property (IP) requirements and formatting standards.

Servicing Australia’s Key Mining Regions

Hamilton By Design proudly supports coal wash plant upgrades and mechanical design projects across Australia’s leading coal regions, including:

Bowen Basin
Surat Basin
Hunter Valley
Newcastle
Central Coast
Western and Central NSW coalfields

Our local experience ensures that we understand the logistical, operational, and environmental challenges unique to each region — helping projects stay compliant, efficient, and on schedule.

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Why Choose Hamilton By Design?

Reduced Downtime: Accurate pre-shutdown planning through digital models.
Improved Safety: Less manual measuring in hazardous or confined areas.
Guaranteed Fit-Up: Fabrication drawings verified against real-world geometry.
Faster Turnaround: Streamlined scanning-to-design-to-fabrication workflow.
Proven Experience: Over two decades in mechanical engineering and plant design.

Our mission is simple — to take the risk out of upgrades by combining engineering insight with digital accuracy.

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“Precision scanning and mechanical design — taking the risk out of plant upgrades.”

Let’s Make Your Next Upgrade Risk-Free

If your next shutdown involves mechanical upgrades, pipework replacement, or structural modifications, talk to Hamilton By Design.

We can help you visualise, plan, and execute upgrades with confidence — reducing downtime, eliminating measurement errors, and delivering safer outcomes for your team.

info@hamiltonbydesign.com.au
www.hamiltonbydesign.com.au

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9 October 202514 January 2026

From 3D Scanning to Digital Twins: The Next Step in Mining Data

Mining is evolving faster than ever.
What was once an industry defined by physical muscle — haul trucks, crushers, conveyors — is now being transformed by data intelligence, digital modelling, and real-time insight.

At the heart of this transformation lies a quiet revolution: 3D scanning.
Once used primarily for design verification or plant modification, scanning is now the gateway technology that feeds the emerging world of digital twins — live, data-driven replicas of mine assets that help engineers predict, plan, and optimise before problems occur.

At Hamilton By Design, we’ve spent years scanning and modelling chutes, hoppers, and material-handling systems across Australia’s mining sector. Each project has shown us one thing clearly:

Scanning isn’t just about geometry — it’s about knowledge.
And digital twins are the next logical step in turning that knowledge into action.

What Exactly Is a Digital Twin?

Think of a digital twin as the digital counterpart of a physical asset — a chute, a conveyor, a processing plant, even an entire mine site.

It’s not a static 3D model; it’s a dynamic, data-linked environment that mirrors the real system in near real time.
Sensors feed performance data into the twin: wear rates, temperature, vibration, flow speed, throughput. The twin then responds, updating its state and allowing engineers to simulate scenarios, forecast failures, and test design changes before touching the physical equipment.

In essence, a digital twin gives you a real-time window into the life of your assets — one that’s predictive, not reactive.

How 3D Scanning Powers the Digital Twin

To create a digital twin, you first need an accurate foundation — and that’s where 3D scanning comes in.
The twin can only be as good as the geometry beneath it.

Laser scanning or LiDAR technology captures millimetre-accurate measurements of chutes, hoppers, crushers, conveyors, and processing structures.
This creates a precise 3D “as-is” model — not what the plant was designed to be, but what it actually is after years of wear, repair, and modification.

That baseline geometry is then aligned with:

Operational data from sensors and PLCs (e.g. flow rates, temperatures, vibrations)
Material behaviour data from CFD and wear simulations
Design intent data from CAD and engineering archives

Once these layers are synchronised, the model becomes a living system — continuously updated, measurable, and comparable to its physical twin.

You can see how we capture and prepare that foundation in our detailed article:
3D Scanning Chutes, Hoppers & Mining

From Reactive Maintenance to Predictive Performance

In most operations today, maintenance still works on a reactive cycle — wait for a fault, shut down, repair, restart.
It’s expensive, unpredictable, and risky.

With digital twins, that model flips.
Instead of waiting for wear to become a failure, the twin uses real-time and historical data to forecast when parts will reach their limits.
The result is predictive maintenance — planning shutdowns based on evidence, not emergency.

Imagine being able to simulate how a chute will behave under new flow conditions, or when a liner will reach its critical wear thickness, before you commit to a shutdown.
That’s not future-speak — it’s what forward-thinking operators are doing right now.

Every hour of avoided downtime can mean tens or even hundreds of thousands of dollars saved.
Even a modest 5 % reduction in unplanned outages can add millions to annual output.

Integrating Scanning, Simulation, and Sensors

A full digital-twin workflow in mining usually includes four steps:

Capture: 3D scanning provides the exact geometry of the asset.
Model: Engineers integrate the geometry with CAD, CFD, and FEA models.
Connect: Real-time data from sensors is linked to the model.
Predict: Algorithms and engineers analyse the twin to predict future performance.

The power lies in connection.
Each new scan or dataset strengthens the model, improving its predictive accuracy. Over time, the digital twin evolves into a decision-support system for engineers, planners, and maintenance teams.

Real-World Applications Across the Mining Value Chain

1. Chute & Hopper Optimisation

Flow issues, blockages, and uneven wear can be modelled digitally before modifications are made.
This reduces trial-and-error shutdowns and improves throughput reliability.

2. Conveyor Alignment

Scanning allows engineers to identify misalignment over kilometres of belting.
A digital twin can then simulate tracking and tension to prevent belt failures.

3. Crusher and Mill Wear

By combining periodic scans with wear sensors, operators can visualise material loss and forecast replacement schedules.

4. Structural Monitoring

3D scanning enables long-term comparison between “as-built” and “as-maintained” geometry, detecting distortion or settlement early.

Each of these applications reinforces a core insight:

The line between mechanical engineering and data engineering is disappearing.

Why Digital Twins Matter for Australia’s Mining Future

Australia’s competitive advantage has always been resource-based.
But the next advantage will be knowledge-based — how well we understand, model, and optimise those resources.

Digital twins represent that shift from raw extraction to engineering intelligence.
They help miners lower costs, reduce emissions, and improve safety, while extending asset life and reliability.

As Australia pushes toward decarbonisation and productivity targets, technologies like scanning and digital twinning will underpin the next generation of sustainable mining design.

The Hamilton By Design Approach

Our philosophy is simple: technology only matters if it serves engineering integrity.
That’s why our process always begins with real-world problems — not software.

Field Capture: We conduct high-resolution 3D scans under live or shutdown conditions.
Engineering Integration: Our designers and mechanical engineers turn that data into usable CAD and FEA models.
Digital Twin Setup: We connect the digital model to operational data, creating a living reference that evolves with the asset.
Continuous Support: We monitor, re-scan, and update as assets change.

This approach ensures every digital twin remains a tool for decision-making, not just a visualisation exercise.

A Connected Knowledge Chain

This article builds on our earlier discussion:

Digital Precision in Mining: How 3D Scanning Transforms Maintenance, Design, and Safety

That piece explored how scanning replaces manual measurement with safe, precise, data-rich modelling.
Digital twins take that same data and carry it forward — connecting it to predictive insights and automated planning.

The flow looks like this:

3D Scan → Model → Digital Twin → Predict → Improve → Re-scan

Each loop makes the operation smarter, safer, and more efficient.

Lessons from Global Mining Leaders

Rio Tinto and BHP are already trialling digital twins for rail networks, conveyors, and entire processing plants.
Anglo American uses twin models to monitor tailings dam integrity, integrating LiDAR scans with geotechnical sensors.
Fortescue has explored twin-based predictive maintenance for haulage and fixed plant systems.

Internationally, countries like Finland and Canada have established digital-twin testbeds for mine ventilation, environmental monitoring, and process control — demonstrating that twinning isn’t a luxury, it’s a competitive necessity.

Looking Forward: The Road to Real-Time Mines

The next decade will see digital twins move from project pilots to enterprise-wide ecosystems.
Future systems will integrate:

IoT sensors streaming continuous data
AI algorithms identifying anomalies in real time
Augmented-reality tools allowing operators to “see” the twin overlaid on the physical plant

Combined, these will make mines safer, cleaner, and more efficient — driven by data instead of downtime.

The Broader Economic Story

The technology’s value doesn’t stop at the mine gate.
As digital twins become standard across energy, infrastructure, and manufacturing, Australia’s engineering capability grows alongside GDP.

Every dollar invested in scanning and twin development creates long-term dividends in productivity and sustainability.
By connecting our data and design skills to resource industries, we strengthen both our domestic economy and our global competitiveness.

Building Smarter, Safer, and More Predictable Mines

Mining will always be a physically demanding industry — but its future will be defined by how intelligently we manage that physicality.

From the first laser scan to the fully connected digital twin, every step tightens the link between information and performance.

At Hamilton By Design, we’re proud to stand at that intersection — where mechanical precision meets digital innovation.
We help our clients not just capture data, but understand it — turning measurements into models, and models into insight.

Because when you can see your mine in full digital clarity, you can shape its future with confidence.

Mechanical Engineering | Structural Engineering

Mechanical Drafting | Structural Drafting

3D CAD Modelling | 3D Scanning

Chute Design

SolidWorks Contractors in Australia

Hamilton By Design – Blog

Custom Designed – Shipping Containers

Coal Chute Design

Mechanical Engineers in Sydney

4 October 202514 January 2026

Opinion: What Cutting 50% of Australia’s Iron Ore Exports to China Would Really Mean

By Anthony Hamilton, Mechanical Engineer and Industry Analyst

Australia’s relationship with China has always been a balancing act between economic dependence and strategic independence. Nowhere is that tension clearer than in our trade of iron ore — the mineral that built both our national budget and China’s skyline.

Imagine, then, a bold decision: Australia deliberately cuts its iron ore exports to China by half and pivots toward domestic manufacturing — especially green steel and renewable-powered industry. What would that mean for our economy, our global influence, and our future as an industrial nation?

The answer is both disruptive and transformative.

The Shock: Short-Term Pain

Let’s be clear: halving iron ore exports would jolt the economy.

Australia exported about 900 million tonnes of iron ore in 2024–25, worth roughly A$160 billion, with China buying four-fifths of it. Slashing that volume by half would pull A$80–90 billion out of export revenue almost overnight. Even if prices spiked 50% amid global shortages, our GDP would still take a hit of 2–3% in the first years — a deliberate, self-imposed economic slowdown.

Western Australia, which lives and breathes the ore trade, would feel it most: reduced royalties, idle capacity, and strained state budgets. Canberra’s tax intake could drop by A$10–15 billion per year in the early phase.

But these are short-term tremors — not structural decline. The question is whether we can replace raw-ore exports with something better: value-added industrial activity on Australian soil.

The Transition: Turning Rocks into Revenue

If half of that diverted ore were converted into green steel, the economic story changes dramatically.
One tonne of steel is worth four to six times more than the same tonne of ore. Even modest domestic processing could create an A$100 billion green industry within a decade — generating thousands of high-skill jobs across hydrogen, renewables, materials science, and engineering.

Projects in Whyalla, Gladstone, and the Pilbara already point the way. With the right investment — perhaps A$60–100 billion over ten years — Australia could build the capacity to supply its own construction, defence, and transport sectors while exporting carbon-neutral steel to the world.

That’s not deglobalisation. It’s smart industrialisation — keeping the value chain at home instead of shipping our competitive advantage overseas.

The Payoff: Long-Term Strength

By 2035, the payoff could be substantial:

GDP grows larger and more balanced, driven by advanced manufacturing.
Australia becomes a reliable producer of green steel, battery materials, and hydrogen infrastructure.
Dependence on Chinese demand declines, while new trade with India, Japan, Korea, and Europe expands.

In this scenario, Australia’s GDP could be 2–4% higher than the business-as-usual case — smaller mining exports, but far greater industrial depth. It’s a shift from volume to value, from being the world’s quarry to being part of its workshop again.

The Risk: A Test of Political Will

Such a move isn’t without risk. China would almost certainly retaliate — delaying other imports, applying political pressure, and exploiting our internal divisions.
The mining lobby would fight hard to protect its margins. Politicians would face the same question every reformer does: why risk the comfortable present for an uncertain future?

Yet the uncomfortable truth is that comfort has bred complacency.
Australia’s prosperity is overly reliant on shipping low-value resources to one buyer. That’s not economic freedom — its dependency dressed as success.

The Opportunity: Building the Next Holden Moment

Half a century ago, Holden symbolised a confident, self-sufficient industrial Australia. Its closure marked the end of that era.
A green-steel renaissance could be the new Holden moment — a chance to reconnect engineering, manufacturing, and national purpose. It would anchor new jobs, restore industrial pride, and ensure that Australia competes not on cost, but on competence.

We’d still dig things up — but we’d also make things again.

Conclusion: A Strategic Rebalance, Not an Economic Gamble

Cutting 50% of iron ore exports to China would be a strategic recalibration, not an act of economic self-harm. It would cost us in the short run, but it could redefine us in the long run — from a resource economy to a resilient, innovation-driven nation.

For decades, Australia’s industrial conversation has ended with one refrain: “We can’t afford to make things anymore.”
Perhaps the truth is the opposite.

We can’t afford not to.

Mechanical Engineering | Structural Engineering

Mechanical Drafting | Structural Drafting

3D CAD Modelling | 3D Scanning

Chute Design

SolidWorks Contractors in Australia

Hamilton By Design – Blog

Custom Designed – Shipping Containers

Coal Chute Design

Mechanical Engineers in Sydney

14 July 202514 January 2026

Harnessing Opportunity in Australia’s $1.2 B Critical Minerals Push

Australia’s Federal Government has announced an A$1.2 billion Critical Minerals Strategic Reserve, backed by a $1 billion top-up to its existing Critical Minerals Facility. With implementation set for the second half of 2026, the Reserve aims to secure critical minerals—lithium, cobalt, nickel, rare earths—through government offtake agreements and strategic stockpiling miningmonthly.com

Why It Matters for Mechanical Engineers

This isn’t just political positioning—it’s a major call to action for mechanical engineering consultancies:

Scale and diversification of processing sites – More projects will need robust mechanical systems from crushing and conveying to structural and structural integrity assessments, especially for rare earths and heavy metals.
Advanced processing technologies – Selective stockpiling and refining of critical minerals will require high-precision mechanical design, wear management, and optimization of machinery performance.
Infrastructure and retrofit demand – The Reserve extends the Critical Minerals Facility’s reach to A$5 billion, catalysing greenfield builds and upgrades—areas where Hamilton By Design excels.

Strategic Insights for Hamilton By Design

At Hamilton By Design, our strength lies in supporting projects from feasibility to commissioning, encompassing:

Materials handling systems – conveyors, stockpiles, chutes
Structural and fatigue engineering – ensuring safety and longevity under harsh industrial conditions
Wear and reliability optimisation – extending lifespan and uptime of mechanical assets
Digital tools – such as FEA, 3D scanning, and digital twins to enhance design accuracy and project efficiency

This Government-backed industrial growth is a signal for mining contractors and OEMs to engage expert mechanical consultants early—ensuring streamlined, compliant, and future-proofed system integration.

🛠️ How Hamilton By Design Adds Value

What You Get	How It Helps
Proven materials-handling systems design	Scalable, reliable conveyors and chutes for critical-mineral plants
End-to-end structural assessments	Enables compliance with WHS, AS/NZS and long-term asset management
Wear analysis & maintenance planning	Reduces downtime and extends asset lifespan
Integration of digital engineering	Improves commissioning, reduces risk and cost overruns

With major investments planned and a strong industrial trajectory ahead, now is the time for OEMs and mining clients to tap into specialist mechanical consulting support.

Let’s talk about how Hamilton By Design can partner to deliver cutting‑edge materials handling and structural engineering solutions for your next critical minerals project.

Hamilton By Design | Mechanical Drafting | Structural Drafting | 3-D Lidar Scanning

13 July 202516 January 2026

Shaping the Future of Mining

Mechanical Engineering & 3D Lidar Scanning in Mount Isa

Posted by Hamilton By Design | Based in Mount Isa | www.hamiltonbydesign.com.au

🔧 Precision Engineering Meets Digital Innovation in the Mining Sector

In the heart of Australia’s mining country—Mount Isa—Hamilton By Design is delivering cutting-edge mechanical engineering solutions powered by 3D Lidar scanning and point cloud modelling.

Whether you’re managing underground infrastructure, fixed plant upgrades, or brownfield expansions, our advanced tools and design expertise help you visualise, optimise, and execute projects with clarity and confidence.

How We Support the Mining Industry

As mechanical engineering consultants, we provide services that reduce project risk, increase design accuracy, and streamline construction workflows. Key areas include:

Lidar 3D Scanning of existing plant, pipework, and underground assets
Point Cloud Creation for clash detection and design validation
Mechanical & Structural Drafting using accurate site data
Reverse Engineering of legacy plant or undocumented assets
Detailed Design for Modifications & Upgrades
Compliance, Auditing, and Risk Reduction

By combining field-tested mechanical engineering with cutting-edge digital capture, we help mining teams make better decisions—faster.

Why Mount Isa?

Mount Isa is home to some of Australia’s largest and most complex mining operations. From Glencore’s copper and zinc mines to contracting hubs servicing the broader North West Minerals Province, this region demands precision, speed, and deep mining knowledge.

Hamilton By Design is based locally in Mount Isa, giving us the unique advantage of rapid site access, practical experience in mining environments, and a strong understanding of local challenges.

Why Use Lidar & Point Clouds?

Lidar scanning has transformed how we approach engineering projects in mining:

Capture complex environments in minutes, not days
Generate ultra-accurate point clouds for design, measurement, and planning
Minimise rework by designing to exact, as-built geometry
Visualise site constraints in 3D before committing to fabrication or install
Integrate scan data with CAD models for seamless design workflows