3D Laser Scanning and Digital Engineering for Coal Handling Plants

Coal handling and preparation plants (CHPPs) are some of the most complex and congested industrial environments in the mining sector. Conveyors, transfer towers, chutes, pumps, structural steel, and access platforms are constantly being modified as plants expand and production requirements change.

Over time, these modifications often mean the original engineering drawings no longer represent what is actually built on site. This creates significant challenges when engineers attempt to upgrade equipment, replace structures, or install new systems.

For this reason, many mining operations are now turning to 3D laser scanning and digital engineering workflows to capture the real-world condition of their plant infrastructure before design work begins.

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Why Coal Handling Plants Need Accurate Site Data

Coal handling facilities operate continuously and typically have very limited shutdown windows for upgrades or maintenance.

If a new chute, conveyor section, or structural modification does not fit correctly during installation, the consequences can include:

• extended shutdown durations

• expensive on-site modifications

• lost production

• safety risks for maintenance teams

Modern engineering teams are increasingly using engineering-grade LiDAR scanning to capture millions of measurement points across existing plant infrastructure. This creates a highly accurate point cloud model of the facility, allowing engineers to design upgrades with confidence.

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3D Laser Scanning in Coal Handling Facilities

3D laser scanning is widely used in mining operations to capture detailed geometry of:

• conveyors and transfer towers

• chutes and hoppers

• pump stations

• pipe racks and ductwork

• structural steel platforms

• process equipment

This technology rapidly records millions of spatial measurements, creating a digital representation of the plant that can be used for engineering design and clash detection.

Instead of relying on tape measures and sketches, engineers can design modifications directly within the digital model.

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Digital Engineering for Shutdown Planning

Mining shutdowns are high-pressure engineering events where every hour counts.

By combining laser scanning with modern CAD tools such as SolidWorks, engineers can create accurate digital models of existing infrastructure before fabrication begins.

This allows teams to:

• check clearances between new and existing equipment

• verify structural connections

• confirm pipe routes and tie-ins

• ensure maintenance access is available

Accurate digital models help ensure that fabricated components fit correctly the first time, reducing rework and helping shutdown projects stay on schedule.

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Mechanical Engineering for Mining Infrastructure

While scanning provides accurate site data, successful plant upgrades still require practical mechanical engineering design.

Mining mechanical engineers work across a wide range of systems, including:

• bulk material handling equipment

• conveyors and transfer stations

• slurry and pump systems

• structural steel infrastructure

• process plant upgrades

Engineering design transforms raw scan data into fabrication-ready drawings and practical solutions that can be installed safely in operating plants.

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Laser Scanning in the Hunter Valley

Regions such as the Hunter Valley in New South Wales contain some of Australia’s largest coal handling and processing facilities.

Many of these plants have been operating for decades and have undergone numerous upgrades and modifications. Accurate digital capture of existing infrastructure allows engineers to safely design improvements while maintaining plant productivity.

Learn more about scanning projects in this region here:

• 👉 https://www.hamiltonbydesign.com.au/hunter-valley-laser-scanning/

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Coal Handling Plant Laser Scanning

Laser scanning is particularly valuable in coal handling plants where equipment is tightly packed and access is difficult.

By capturing accurate geometry of conveyors, chutes, and structural steel, engineers can develop precise digital models that support plant upgrades and maintenance planning.

You can read more about this approach here:

• 👉 https://www.hamiltonbydesign.com.au/coal-handling-plant-laser-scanning/

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Reducing Shutdown Risk with Digital Engineering

Combining scanning with mechanical engineering design allows engineers to create digital engineering models of industrial plants.

These models allow teams to simulate installations, verify fit-up, and prepare detailed fabrication drawings before work begins on site.

Learn more about this workflow here:

• 👉 https://www.hamiltonbydesign.com.au/reducing-shutdown-risk-digital-engineering-models/

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Mining Mechanical Engineering Design

Digital capture and modelling technologies are powerful tools, but the real value comes from combining them with practical mining engineering experience.

Hamilton By Design provides mechanical engineering services that support mining operations with plant upgrades, equipment design, and infrastructure improvements.

More information can be found here:

• 👉 https://www.hamiltonbydesign.com.au/mining-mechanical-engineering-design/

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Final Thoughts

Modern mining infrastructure projects rely on a combination of:

• 3D laser scanning

• digital plant modelling

• practical mechanical engineering design

Together, these tools allow engineers to capture existing plant conditions, design upgrades accurately, and reduce risks during shutdown installation work.

For coal handling plants and mineral processing facilities, this approach helps ensure that new equipment fits correctly, shutdowns run smoothly, and production losses are minimised.

 

3D Laser Scanning for Industrial Plants in Orange NSW

Industrial plants often evolve over decades. Equipment is modified, pipework is rerouted, structures are reinforced, and new systems are added during shutdowns or upgrades.

Over time, the original engineering drawings rarely reflect the true condition of the plant. This can make mechanical upgrades, structural modifications, and plant expansions far more difficult than expected.

For this reason, many engineering teams now use 3D laser scanning to capture the real-world geometry of industrial facilities before design work begins.

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Why Industrial Plants Need Accurate Existing Condition Data

In mining and heavy industry, many projects occur in brownfield environments where equipment and infrastructure already exist.

Without accurate site information, engineers often encounter problems such as:

• Pipe clashes during installation

• Structural steel conflicts

• Equipment that does not fit the allocated space

• Maintenance access issues

• Unexpected shutdown delays

3D laser scanning helps eliminate these risks by capturing the true geometry of the plant environment.

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What is 3D Laser Scanning?

3D laser scanning uses LiDAR technology to capture millions of spatial measurements within an industrial environment.

The result is a point cloud dataset, which represents the plant as a highly accurate digital model.

Engineers can then convert this data into:

• 3D plant models

• structural steel layouts

• equipment models

• pipework routing

• engineering drawings

This approach allows designers to work with real-world data instead of assumptions.

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Applications in Mining and Industrial Engineering

3D scanning is widely used in mining infrastructure projects, including:

Plant Upgrades

Capturing the existing plant layout allows engineers to design new equipment installations without clashes.

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Shutdown Preparation

Shutdown work is often tightly scheduled. Accurate plant models help ensure prefabricated equipment fits correctly when installed.

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Structural Steel Design

Laser scans allow engineers to design new structures that integrate with existing columns, beams, and platforms.

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Mechanical Equipment Installation

Engineers can verify space envelopes for pumps, conveyors, tanks, and process equipment.

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Digital Engineering Workflows

Once captured, the point cloud can be imported into engineering software such as:

• SolidWorks

• AutoCAD

• plant design platforms

• structural modelling tools

This allows engineers to build accurate digital twins of industrial plants and design upgrades with confidence.

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Industrial 3D Scanning in Orange NSW

Industrial regions such as Orange in New South Wales contain a wide range of facilities including mining infrastructure, processing plants, and industrial workshops.

Capturing these facilities with engineering-grade 3D laser scanning provides the accurate data needed to support plant upgrades, shutdown planning, and equipment installation projects.

You can read the full article explaining how this technology is used in industrial environments here:

👉 3D Scanning for Industrial Plants in Orange NSW
https://www.hamiltonbydesign.com.au/3d-scanning-industrial-orange/

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Mining Infrastructure Engineering

This blog focuses on practical engineering topics relevant to mining and heavy industry, including:

• mining plant equipment design

• structural steel infrastructure

• materials handling systems

• pump and piping systems

• digital engineering and plant modelling

If you are involved in mechanical engineering design for mining infrastructure, follow this blog for practical insights and engineering discussions.

 

Pump Skid Design for Mining Plants

Why Good Mechanical Design Matters

In many mining and mineral processing plants, pump skids are one of the most common modular equipment packages used for fluid handling systems.

They are typically used for:

• slurry transfer

• process water circulation

• chemical dosing systems

• mine dewatering

• fuel transfer systems

• thickener and tailings systems

A pump skid integrates the pump, driver (motor or engine), piping, valves, instruments, and controls onto a single structural base frame so the system can be installed as a single module.

This modular approach is widely used in mining infrastructure because it simplifies installation, improves maintenance access, and reduces construction time on site.

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What is a Pump Skid?

A typical industrial pump skid consists of several integrated components mounted on a steel base frame:

• Pump (centrifugal, slurry, progressive cavity, etc.)

• Electric motor or diesel engine

• Structural baseplate

• Pipework and valves

• Pressure instrumentation

• Control systems

• Lifting points and transport frames

The goal of a skid system is to deliver a complete functional pumping unit that can be transported, installed, and commissioned with minimal site work.

In mining plants, these systems often need to operate in harsh environments with vibration, abrasive fluids, and difficult access conditions, which makes good engineering design essential.

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Why Pump Skid Design is Critical in Mining

Poorly designed pump skids are responsible for many operational problems in processing plants.

Common design issues include:

• misalignment between pump and motor

• pipework loads transferred into the pump casing

• inadequate maintenance access

• structural vibration or frame distortion

• poor lifting and transport design

• instrumentation located in inaccessible areas

These problems can lead to:

• premature pump failures

• seal leaks

• excessive vibration

• shutdown delays during maintenance

Good engineering design ensures the pump skid performs reliably for many years.

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Engineering Considerations in Pump Skid Design

Mechanical engineers typically consider several factors when designing pump skids for mining operations.

Structural Frame Design

The skid base must support:

• pump weight

• dynamic loads during operation

• transport loads during lifting or relocation

In mining environments, frames are typically fabricated from heavy steel sections with lifting lugs and forklift pockets.

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Piping and Mechanical Loads

Pipe loads are one of the most common causes of pump failures.

Designers must ensure:

• suction piping avoids air pockets

• pipe supports remove load from the pump nozzles

• flexible joints or expansion allowances are included

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Maintenance and Access

Mining plants must maintain equipment quickly during shutdowns.

Good skid design includes:

• clear access to mechanical seals

• removable guards

• accessible valves and gauges

• safe lifting points for pump removal

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Integration with Existing Plants

Many pump skid installations occur during brownfield upgrades.

Modern engineering workflows often use 3D laser scanning and digital modelling to ensure new equipment fits correctly within existing infrastructure.

This approach helps engineers avoid:

• pipe clashes

• access conflicts

• structural interference

• installation delays

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Designing Pump Skids with SolidWorks and Digital Engineering

Modern mining engineering projects increasingly rely on 3D modelling and digital engineering tools.

Using software such as SolidWorks, engineers can:

• build complete skid assemblies

• simulate installation clearances

• design structural frames

• verify maintenance access

• produce fabrication drawings

This approach reduces risk during fabrication and installation.

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Learn More About Pump Skid Engineering

If you want to understand how engineers design pump skids for mining plants, including structural frames, piping integration, and fabrication deliverables, read the full article here:

👉 Pump Skid Design for Mining Plants
https://www.hamiltonbydesign.com.au/pump-skid-design-mining/

The page explains how mechanical engineering design, digital modelling, and practical plant experience combine to deliver reliable pump systems for mining operations.

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Mining Infrastructure Engineering

The Mining Infrastructure – SolidWorks Design blog explores practical engineering topics such as:

• plant equipment design

• transfer chutes and materials handling

• structural steel for mining plants

• pump systems and piping layouts

• digital plant modelling

If you are involved in mining mechanical engineering, plant upgrades, or equipment design, follow this blog for practical insights.

From Point Cloud to Engineering Model – Mining Infrastructure and SolidWorks Design

From Point Cloud to Engineering Model – Mining Infrastructure and SolidWorks Design

Modern mining and industrial infrastructure projects increasingly rely on accurate digital representations of existing plant conditions before design or upgrade work begins. One of the most effective ways to achieve this is through 3D laser scanning and point cloud modelling, which allows engineers to capture millions of measurements from real-world facilities and convert them into usable engineering models.

On the Mining Infrastructure and SolidWorks Design platform, we often explore how digital engineering tools support industrial projects. A key example is the point cloud to engineering model workflow, where laser scanning data is transformed into detailed CAD models used for design, retrofit engineering, and plant upgrades.

Laser scanners capture dense datasets known as point clouds, where each point represents a precise coordinate in three-dimensional space. These points collectively form a highly accurate digital representation of the facility that can later be converted into engineering models and drawings.

However, raw point cloud data is not yet an engineering model. Engineers must process and interpret the scan data to convert the unstructured measurements into usable CAD geometry and design information. This transformation bridges the gap between real-world infrastructure and digital engineering workflows.

Supporting Mining Infrastructure Design

In mining environments, existing plant documentation is often incomplete or outdated. Laser scanning allows engineers to rapidly capture:

• Processing plants

• Structural steel and platforms

• Pipework systems

• Conveyors and mechanical equipment

• Tanks, vessels, and maintenance access areas

By converting the captured data into SolidWorks or CAD engineering models, engineers can perform design validation, clash detection, and upgrade planning before any physical modifications begin.

Hamilton By Design – Engineering Reality Capture

Hamilton By Design specialises in engineering-grade laser scanning and digital modelling for mining and industrial infrastructure projects across Australia. Their workflow focuses on capturing accurate site conditions and converting scan data into usable engineering models for design and upgrade projects.

The process typically includes:

1. Industrial laser scanning of plant infrastructure

2. Registration and processing of point cloud data

3. Importing point clouds into CAD and SolidWorks environments

4. Creating engineering models from scanned conditions

5. Using the models for design development and plant upgrades

This workflow allows engineers to move from raw scan data to accurate engineering models, reducing project risk and improving design coordination.

Learn More

For a detailed explanation of the full workflow from laser scanning to engineering model creation, visit the article below from Hamilton By Design:

From Point Cloud to Engineering Model Workflow
https://www.hamiltonbydesign.com.au/point-cloud-to-engineering-model-workflow/

The article explores how engineers transform real-world industrial environments into digital engineering models used for mining infrastructure upgrades, shutdown planning, and plant design projects.

Materials Handling Engineering for Mining Infrastructure and Plant Design

Bulk materials handling systems remain one of the most critical components of modern mining and heavy industrial infrastructure. Equipment such as conveyors, hoppers, transfer chutes, stackers, reclaimers, and processing plant equipment must be designed to operate reliably in demanding environments.

Mechanical designers working in the mining industry require a strong understanding of materials handling equipment, plant processes, and industrial infrastructure. Modern engineering teams also rely heavily on advanced 3D modelling tools such as SolidWorks to develop accurate designs and coordinate plant modifications.

At Hamilton By Design, engineering workflows combine practical mining experience with modern digital engineering tools to support materials handling projects across Australia.

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Mechanical Design for Bulk Materials Handling

Bulk materials handling equipment is commonly used in:

• Mining processing plants

• Port and rail infrastructure

• Materials transfer systems

• Crushing and screening plants

• Processing facilities and refineries

Mechanical designers working in this space often design and document systems including:

• Conveyor structures and transfer stations

• Material handling chutes

• Structural steel platforms and access systems

• Pipework and process equipment

• Fixed plant mechanical infrastructure

Accurate design documentation and engineering models are essential to ensure these systems operate efficiently and safely within existing plant infrastructure.

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Engineering Design with SolidWorks

Modern mining infrastructure projects rely on 3D CAD platforms such as SolidWorks to develop engineering models for complex industrial equipment.

SolidWorks allows engineers and designers to:

• Develop detailed mechanical assemblies

• Model bulk materials handling systems

• Produce fabrication and workshop drawings

• Coordinate plant modifications with existing infrastructure

• Support engineering analysis and design validation

Using 3D modelling tools also allows engineering teams to visualise how new equipment will integrate into existing plant environments.

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Capturing Existing Plant Infrastructure

Many mining and industrial facilities have evolved over decades, which means existing drawings may not accurately represent the current plant configuration. Engineers increasingly rely on 3D laser scanning and point cloud modelling to capture accurate site conditions before design begins.

Hamilton By Design provides engineering-grade laser scanning services for mining and industrial infrastructure projects, allowing engineers to capture millions of spatial measurements from real-world plant environments.

Learn more about these services:

Engineering-Grade 3D Laser Scanning for Mining and Industrial Projects
https://www.hamiltonbydesign.com.au/home/engineering-grade-3d-laser-scanning-mining-industrial/

3D Laser Scanning Across Australia
https://www.hamiltonbydesign.com.au/home/engineering-services/3d-laser-scanning/3d-laser-scanning-across-australia/

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Supporting Mining Plant Upgrades

Laser scanning and digital modelling are increasingly used to support mining plant upgrades and retrofit engineering projects. By capturing accurate existing conditions, engineers can design new equipment and structural modifications with greater confidence.

Hamilton By Design supports mining operators with engineering-grade scanning and modelling services specifically for plant upgrades.

Engineering-Grade 3D Laser Scanning for Mining Plant Upgrades
https://www.hamiltonbydesign.com.au/engineering-grade-3d-laser-scanning-mining-plant-upgrades/

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Engineering Support for Mining Shutdown Projects

Shutdown projects often involve complex modifications to materials handling systems, structural steel, and mechanical equipment. Accurate plant data is essential to ensure new components fit correctly during shutdown installation windows.

Laser scanning allows engineering teams to develop accurate models of plant infrastructure before shutdown work begins.

3D Laser Scanning for Mining Shutdown Projects
https://www.hamiltonbydesign.com.au/3d-laser-scanning-mining-shutdowns/

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Capturing Existing Conditions Before Plant Upgrades

One of the most important steps in any engineering upgrade project is capturing the true existing conditions of the plant environment.

Hamilton By Design explains this process in more detail in the following article:

How Engineers Capture Existing Conditions Before Plant Upgrades
https://www.hamiltonbydesign.com.au/capture-existing-conditions-before-plant-upgrades/

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Engineering Services for Mining Infrastructure

Hamilton By Design works with mining operators, engineering firms, and industrial clients to support mechanical design, engineering modelling, and reality capture services across Australia.

By combining laser scanning, point cloud modelling, and SolidWorks engineering design, engineers can develop more accurate solutions for materials handling systems and mining infrastructure projects.

To learn more about these engineering workflows, visit the Hamilton By Design website:

https://www.hamiltonbydesign.com.au/

Material Handling Design

From Point Cloud to Engineering Model Workflow – Mining Infrastructure and SolidWorks Design

Modern mining and industrial facilities are complex environments where accurate information about existing plant infrastructure is critical before design or upgrade work begins. Traditional drawings are often outdated or incomplete, which can introduce risk during plant modifications, shutdown upgrades, or equipment installations.

One of the most effective methods engineers now use to overcome this challenge is 3D laser scanning and point cloud modelling. This technology allows engineers to capture millions of spatial measurements from real-world infrastructure and convert them into digital engineering models used for design and planning.

The process of converting point cloud data into engineering CAD models is commonly referred to as the point cloud to engineering model workflow.

For a detailed explanation of this workflow, see the article from Hamilton By Design:

From Point Cloud to Engineering Model Workflow – Hamilton By Design Co.
https://www.hamiltonbydesign.com.au/point-cloud-to-engineering-model-workflow/

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Reality Capture for Mining Infrastructure

Laser scanning technology allows engineers to rapidly capture industrial facilities with high accuracy. Using specialised scanning equipment, engineers can record millions of measurement points across plant infrastructure including:

• Structural steel

• Pipework systems

• Conveyors and material handling equipment

• Processing plant infrastructure

• Tanks and vessels

• Maintenance access platforms

The captured measurements form a point cloud, which represents the real-world geometry of the facility in three-dimensional space.

Hamilton By Design provides engineering-grade laser scanning services for mining and industrial projects, helping engineering teams capture accurate site conditions before design work begins.

Learn more about their scanning services here:

Engineering-Grade 3D Laser Scanning for Mining and Industrial Projects
https://www.hamiltonbydesign.com.au/home/engineering-grade-3d-laser-scanning-mining-industrial/

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From Point Cloud Data to Engineering Models

Once the point cloud data has been captured and processed, engineers can import the data into CAD environments such as SolidWorks and other engineering design platforms.

Using the point cloud as a reference, engineers can create detailed engineering models that represent:

• Structural steel frameworks

• Mechanical equipment layouts

• Pipe routing and pipe supports

• Maintenance access structures

• Equipment foundations

These models allow engineers to accurately design upgrades and modifications while ensuring new components fit within the existing infrastructure.

Hamilton By Design works with mining and industrial clients across the country to support these workflows.

3D Laser Scanning Across Australia
https://www.hamiltonbydesign.com.au/home/engineering-services/3d-laser-scanning/3d-laser-scanning-across-australia/

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Supporting Plant Upgrades and Shutdown Projects

One of the key advantages of laser scanning is its ability to support plant upgrade projects and shutdown engineering. When existing conditions are captured accurately, engineers can design upgrades with greater confidence and reduce the risk of costly rework during installation.

Laser scanning is commonly used during:

• Processing plant upgrades

• Conveyor modifications

• Structural steel upgrades

• Equipment replacement projects

• Mining plant shutdown works

Hamilton By Design provides specialised scanning and modelling services specifically for these types of projects.

Engineering-Grade Laser Scanning for Mining Plant Upgrades
https://www.hamiltonbydesign.com.au/engineering-grade-3d-laser-scanning-mining-plant-upgrades/

3D Laser Scanning for Mining Shutdown Projects
https://www.hamiltonbydesign.com.au/3d-laser-scanning-mining-shutdowns/

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Capturing Existing Conditions Before Plant Upgrades

One of the most important steps in any industrial engineering project is capturing accurate existing conditions before design begins. When engineers rely solely on outdated drawings, there is a high risk that the new design will not align with the real infrastructure.

Laser scanning solves this problem by providing a highly accurate digital record of the plant environment.

Hamilton By Design explains this process in detail in the following article:

Capturing Existing Conditions Before Plant Upgrades
https://www.hamiltonbydesign.com.au/capture-existing-conditions-before-plant-upgrades/

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Engineering Design for Mining Infrastructure

As mining infrastructure continues to evolve, the combination of laser scanning, point cloud modelling, and CAD engineering design is becoming an essential part of modern plant engineering workflows.

By transforming real-world infrastructure into accurate digital engineering models, engineers can plan plant upgrades more effectively, coordinate designs between disciplines, and reduce risk during construction and shutdown execution.

The point cloud to engineering model workflow represents an important bridge between reality capture and engineering design, enabling more accurate planning for mining and industrial projects.

To learn more about this workflow and how it supports engineering design, visit:

From Point Cloud to Engineering Model Workflow – Hamilton By Design Co.
https://www.hamiltonbydesign.com.au/point-cloud-to-engineering-model-workflow/