AIET |

Robotics

Industrial Robotics for Robust, Production-Ready Automation

From collaborative robots to turnkey robotic cells — AIET Group designs and integrates safe, production-ready automation for manufacturers across aerospace, MRO, defence, energy, and advanced industry.

Speak to an expert

Speak to an expert

Speak to an expert

Engineered Robotic Solutions for Smart, Flexible Manufacturing

Engineered Robotic Solutions for Smart, Flexible Manufacturing

AIET delivers robotics that improves throughput, consistency, and safety — without over-engineering: collaborative automation where flexibility matters, and fully automated cells where cycle time and repeatability drive value.

From feasibility and safety concept through to commissioning and support, we build robotic solutions that perform reliably in real production environments.

Consultancy & Feasibility

Robotics feasibility, cycle time modelling, layout concepts, ROI cases, and risk assessments — designed for practical implementation.

Consultancy & Feasibility

Robotics feasibility, cycle time modelling, layout concepts, ROI cases, and risk assessments — designed for practical implementation.

Consultancy & Feasibility

Robotics feasibility, cycle time modelling, layout concepts, ROI cases, and risk assessments — designed for practical implementation.

Automation Upgrades

Upgrade manual stations with robotics, improve existing cells, and retrofit automation around legacy equipment to increase productivity without full line replacement.

Automation Upgrades

Upgrade manual stations with robotics, improve existing cells, and retrofit automation around legacy equipment to increase productivity without full line replacement.

Automation Upgrades

Upgrade manual stations with robotics, improve existing cells, and retrofit automation around legacy equipment to increase productivity without full line replacement.

Turnkey Robotic Cells

Design, build and integrate complete robotic workcells — including end-of-arm tooling, safety, fixtures, conveyors, guarding, and commissioning.

Turnkey Robotic Cells

Design, build and integrate complete robotic workcells — including end-of-arm tooling, safety, fixtures, conveyors, guarding, and commissioning.

Turnkey Robotic Cells

Design, build and integrate complete robotic workcells — including end-of-arm tooling, safety, fixtures, conveyors, guarding, and commissioning.

Safety, Validation & Systems Integration

Safety-engineered robotic systems with clear recovery modes, compliance documentation, and integration into PLCs, MES/QMS, and digital traceability platforms.

Safety, Validation & Systems Integration

Safety-engineered robotic systems with clear recovery modes, compliance documentation, and integration into PLCs, MES/QMS, and digital traceability platforms.

Safety, Validation & Systems Integration

Safety-engineered robotic systems with clear recovery modes, compliance documentation, and integration into PLCs, MES/QMS, and digital traceability platforms.

AUTOMOTIVE FACTORY ROBOTICS
AUTOMOTIVE FACTORY ROBOTICS
AUTOMOTIVE FACTORY ROBOTICS

Why AIET | ROBOTICS

Robotic automation built for real production environments

Industrial robotics must operate reliably across shifts, operators, and changing production demands. AIET designs robotic systems that account for real factory conditions — including part variation, upstream and downstream processes, safety interactions, and maintenance realities.

Our focus is on building automation that integrates cleanly into production, delivers consistent performance, and remains practical to operate and support over its full lifecycle.

Where robotics adds the most value

Repeatable tasks where consistency and accuracy are critical

Repeatable tasks where consistency and accuracy are critical

Repeatable tasks where consistency and accuracy are critical

Operations limited by manual handling or ergonomic constraints

Operations limited by manual handling or ergonomic constraints

Operations limited by manual handling or ergonomic constraints

Processes requiring stable cycle times across shifts

Processes requiring stable cycle times across shifts

Processes requiring stable cycle times across shifts

Applications where safety or fatigue is a risk factor

Applications where safety or fatigue is a risk factor

Applications where safety or fatigue is a risk factor

Production steps that benefit from controlled, predictable motion

Production steps that benefit from controlled, predictable motion

Production steps that benefit from controlled, predictable motion

Integrated into the wider manufacturing system

Robotics combined with sensing, vision, or measurement where required

Robotics combined with sensing, vision, or measurement where required

Robotics combined with sensing, vision, or measurement where required

Alignment with inspection, quality, and traceability workflows

Alignment with inspection, quality, and traceability workflows

Alignment with inspection, quality, and traceability workflows

Interface with machine vision and metrology inspection stations

Interface with machine vision and metrology inspection stations

Interface with machine vision and metrology inspection stations

Robotics & Automation Integration

Part localisation using machine vision guidance

Part localisation using machine vision guidance

Part localisation using machine vision guidance

High-speed inspection linked to industrial robot control

High-speed inspection linked to industrial robot control

High-speed inspection linked to industrial robot control

Cell layouts that prioritise visibility, access, and workflow

Cell layouts that prioritise visibility, access, and workflow

Cell layouts that prioritise visibility, access, and workflow

Documentation and training aligned with production use

Documentation and training aligned with production use

Documentation and training aligned with production use

Typical Robotic Applications

Automated part handling between production, inspection, and measurement stations

Automated part handling between production, inspection, and measurement stations

Automated part handling between production, inspection, and measurement stations

Robotic loading and unloading of machine tools and test equipment

Robotic loading and unloading of machine tools and test equipment

Robotic loading and unloading of machine tools and test equipment

Vision-guided pick and place for orientation, alignment, and verification

Vision-guided pick and place for orientation, alignment, and verification

Vision-guided pick and place for orientation, alignment, and verification

Metrology-assisted handling for surface, dimensional, or form measurement

Metrology-assisted handling for surface, dimensional, or form measurement

Metrology-assisted handling for surface, dimensional, or form measurement

Transfer of components through inspection, rework, and verification loops

Transfer of components through inspection, rework, and verification loops

Transfer of components through inspection, rework, and verification loops

Collaborative robotic assistance for repetitive or ergonomically challenging tasks

Collaborative robotic assistance for repetitive or ergonomically challenging tasks

Collaborative robotic assistance for repetitive or ergonomically challenging tasks

Kitting, staging, and buffering between process steps

Kitting, staging, and buffering between process steps

Kitting, staging, and buffering between process steps

Designed for Compliance, Safety, and Validation

Risk assessment and safety concept development from the outset

Risk assessment and safety concept development from the outset

Risk assessment and safety concept development from the outset

Safety-engineered control architecture and operating modes

Safety-engineered control architecture and operating modes

Safety-engineered control architecture and operating modes

Guarding, scanners, interlocks, and collaborative safety where applicable

Guarding, scanners, interlocks, and collaborative safety where applicable

Guarding, scanners, interlocks, and collaborative safety where applicable

Clear validation, testing, and acceptance procedures

Clear validation, testing, and acceptance procedures

Clear validation, testing, and acceptance procedures

Documentation to support regulated and audited environments

Documentation to support regulated and audited environments

Documentation to support regulated and audited environments

Alignment with quality, traceability, and production standards

Alignment with quality, traceability, and production standards

Alignment with quality, traceability, and production standards

Practical operator training and handover for safe ongoing use

Practical operator training and handover for safe ongoing use

Practical operator training and handover for safe ongoing use

WHY ROBOTICS OPERATOR TESTING ROBOT

AIET | Vision

Why adopt robotics?

Industrial robotics is increasingly adopted not to remove people, but to stabilise processes, improve safety, and increase predictable output in demanding manufacturing environments.

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WHY ROBOTICS OPERATOR TESTING ROBOT

AIET | Vision

Why adopt robotics?

Industrial robotics is increasingly adopted not to remove people, but to stabilise processes, improve safety, and increase predictable output in demanding manufacturing environments.

Speak to an expert

WHY ROBOTICS OPERATOR TESTING ROBOT

AIET | Vision

Why adopt robotics?

Industrial robotics is increasingly adopted not to remove people, but to stabilise processes, improve safety, and increase predictable output in demanding manufacturing environments.

Speak to an expert

Stabilise production performance

Robotics reduces variability in critical operations, maintaining consistent output and quality.

Stabilise production performance

Robotics reduces variability in critical operations, maintaining consistent output and quality.

Stabilise production performance

Robotics reduces variability in critical operations, maintaining consistent output and quality.

Improve safety and ergonomics

Automating repetitive or physically demanding tasks lowers injury risk and improves working conditions.

Improve safety and ergonomics

Automating repetitive or physically demanding tasks lowers injury risk and improves working conditions.

Improve safety and ergonomics

Automating repetitive or physically demanding tasks lowers injury risk and improves working conditions.

Increase flexibility without complexity

Modern robotic systems enable adaptable automation without rigid, single-purpose machinery.

Increase flexibility without complexity

Modern robotic systems enable adaptable automation without rigid, single-purpose machinery.

Increase flexibility without complexity

Modern robotic systems enable adaptable automation without rigid, single-purpose machinery.

Support quality and compliance

Robotics integrates naturally with inspection, traceability, and validation workflows in regulated industries.

Support quality and compliance

Robotics integrates naturally with inspection, traceability, and validation workflows in regulated industries.

Support quality and compliance

Robotics integrates naturally with inspection, traceability, and validation workflows in regulated industries.

Robotics Applications by Industry

AIET supports organisations where automation must be reliable, defensible, and engineered for high-value processes rather than mass production alone.

Discuss your application

Discuss your application

Discuss your application

Aerospace & Defence Manufacturing

Robotic automation for precision processes, controlled handling, and compliant production — integrated with quality, traceability, and inspection workflows required in regulated aerospace and defence manufacturing.

Robotic assistance for precision processes

Robotic assistance for precision processes

Robotic assistance for precision processes

Controlled handling of high-value components

Controlled handling of high-value components

Controlled handling of high-value components

Automation aligned with quality and documentation requirements

Automation aligned with quality and documentation requirements

Automation aligned with quality and documentation requirements

Automating machine vision and metrology inspection

Automating machine vision and metrology inspection

Automating machine vision and metrology inspection

Flexible robotic cells for mixed production

Flexible robotic cells for mixed production

Flexible robotic cells for mixed production

Machine tending and internal material flow

Machine tending and internal material flow

Machine tending and internal material flow

Automation supporting digital manufacturing strategies

Automation supporting digital manufacturing strategies

Automation supporting digital manufacturing strategies

Collaborative workstation for safe, interactive processes

Collaborative workstation for safe, interactive processes

Collaborative workstation for safe, interactive processes

Advanced Manufacturing & Smart Factories

Flexible robotic automation supporting mixed production, machine tending, and internal material flow — integrated into digital manufacturing strategies and scalable smart factory deployments.

Aviation & MRO

Robotic support for repeatable maintenance, inspection, and handling tasks — improving consistency, safety, and turnaround time within constrained aviation and MRO environments.

Robotic support for repeatable maintenance operations

Robotic support for repeatable maintenance operations

Robotic support for repeatable maintenance operations

Improved consistency across inspection and handling tasks

Improved consistency across inspection and handling tasks

Improved consistency across inspection and handling tasks

Safer workflows in constrained environments

Safer workflows in constrained environments

Safer workflows in constrained environments

Robotic inspection of avaition components

Robotic inspection of avaition components

Robotic inspection of avaition components

Configurable robotic platforms for development and trials

Configurable robotic platforms for development and trials

Configurable robotic platforms for development and trials

Safe experimentation without over-engineering

Safe experimentation without over-engineering

Safe experimentation without over-engineering

Integration with measurement and analysis systems

Integration with measurement and analysis systems

Integration with measurement and analysis systems

Latest generation collaborative robotics for safety

Latest generation collaborative robotics for safety

Latest generation collaborative robotics for safety

Research, Universities & Innovation Labs

Configurable robotic platforms for experimentation, development, and validation — enabling safe testing, measurement integration, and scalable automation research without over-engineering.

Government, Free Zones & National Industrial Programmes

Robotics feasibility, adoption frameworks, and capability-building support — translating industrial policy and transformation objectives into practical, deployable automation solutions.

Robotics feasibility and adoption frameworks

Robotics feasibility and adoption frameworks

Robotics feasibility and adoption frameworks

Capability-building initiatives

Capability-building initiatives

Capability-building initiatives

Support for industrial transformation objectives

Support for industrial transformation objectives

Support for industrial transformation objectives

Our technology partners

AIET integrates proven robotics platforms and automation technologies selected for reliability, long-term support, and suitability to the application. We remain vendor-agnostic where appropriate, ensuring technology choices serve the process — not commercial bias.

Frequently asked questions

Common questions we’re asked before starting a robotic project

Schedule a call

Let’s talk about your application and how AIET Group can help you.

Speak to an expert

Do you prefer email? We're available at:

sales@aietgroup.ae

Schedule a call

Let’s talk about your application and how AIET Group can help you.

Speak to an expert

Do you prefer email? We're available at:

sales@aietgroup.ae

Schedule a call

Let’s talk about your application and how AIET Group can help you.

Speak to an expert

Do you prefer email? We're available at:

sales@aietgroup.ae

Do you integrate collaborative and industrial robots?
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Yes. Selection is based on risk, payload, speed, accuracy, and operational context — not trend.

Can robotics work in high-mix production?
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Yes, when designed correctly. We focus on sensible automation boundaries and flexible system design.

How do you approach safety?
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Safety architecture is engineered from the outset, including risk assessment, control systems, guarding, and operator recovery behaviour.

Do you provide complete robotic cells?
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Yes. From concept through commissioning, documentation, and training.

Can robotics be combined with vision or metrology?
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Yes. We regularly integrate robotics with sensing, inspection, and measurement where it adds technical value.

Do you integrate collaborative and industrial robots?
icon

Yes. Selection is based on risk, payload, speed, accuracy, and operational context — not trend.

Can robotics work in high-mix production?
icon

Yes, when designed correctly. We focus on sensible automation boundaries and flexible system design.

How do you approach safety?
icon

Safety architecture is engineered from the outset, including risk assessment, control systems, guarding, and operator recovery behaviour.

Do you provide complete robotic cells?
icon

Yes. From concept through commissioning, documentation, and training.

Can robotics be combined with vision or metrology?
icon

Yes. We regularly integrate robotics with sensing, inspection, and measurement where it adds technical value.

Do you integrate collaborative and industrial robots?
icon

Yes. Selection is based on risk, payload, speed, accuracy, and operational context — not trend.

Can robotics work in high-mix production?
icon

Yes, when designed correctly. We focus on sensible automation boundaries and flexible system design.

How do you approach safety?
icon

Safety architecture is engineered from the outset, including risk assessment, control systems, guarding, and operator recovery behaviour.

Do you provide complete robotic cells?
icon

Yes. From concept through commissioning, documentation, and training.

Can robotics be combined with vision or metrology?
icon

Yes. We regularly integrate robotics with sensing, inspection, and measurement where it adds technical value.