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MRFs are playing it smart
23 February, 2026
MRFs in the UAE are increasingly embracing advanced technologies such as AI, automation, and real-time data analytics to transform how waste is sorted, processed, and repurposed.
It’s safe to say that smart technologies now shape much of our daily lives. From mundane household tasks to complex industrial operations, automation, AI, and data-driven decision-making are driving efficiency. And the waste management and recycling sector is no exception. In the Middle East, Materials Recovery Facilities (MRFs) handle thousands of tons of waste daily, sorting, separating, and preparing recyclable materials such as ferrous and non-ferrous metals, plastics, paper, and glass for reuse.
As waste volumes grow and demand for high-quality feedstock increases, MRFs are increasingly embracing advanced technologies such as AI, automation, and real-time data analytics to transform how waste is sorted, processed, and repurposed. From smart sensors that identify materials on the fly to robotic arms that separate recyclables with precision, these innovations are reshaping operational efficiency.
One leading example is FARZ MRF, launched by Imdaad in 2020, one of the largest fully automated MRFs in the region. Using advanced separation and recovery technologies, FARZ segregates and reclaims valuable materials, including ferrous and non-ferrous metals, PET, HDPE, PE bags, Old Corrugated Cardboard, and wood from commercial and industrial (C&I) streams. “It has adopted several emerging automation and AI-enabled technologies, with core innovation being sensor-based optical sorting combined with automated mechanical separation, significantly reducing reliance on manual sorting,” explained Haitham Safeyeldin, Chief Operating Officer, Imdaad Group.
Across the UAE, similar advancements, including AI-assisted robotic arms, computer vision systems, and automated quality inspection platforms, have demonstrated clear operational benefits. Several large-scale MRFs now deploy AI-powered robotic sorting systems capable of identifying and separating mixed recyclables in real time.
“These technologies have led to higher processing throughput, improved consistency in sorting decisions, and significantly enhanced material purity, particularly for plastics, metals, and paper. Facilities can now recover greater quantities of high-quality recyclables while reducing contamination and reliance on manual sorting, supporting both economic efficiency and national landfill-diversion targets,” Safeyeldin added.
Technologies like these allow MRFs to process higher volumes of mixed waste. For instance, FARZ handles up to 1,200 tons per day, while maintaining consistent performance. Automation also improves material quality by reducing cross-contamination, producing higher-grade recyclables readily accepted by local and international markets. This directly contributes to higher landfill diversion rates, lower rejection rates from recyclers, and improved economic viability of recycling, aligning with national sustainability objectives.
Similarly, Dulsco Environment MRF in Ras Al Khor operates with mature mechanized sorting infrastructure, including trommel separators, magnetic separators, eddy current systems, ballistic separators, and balers, while exploring AI-assisted robotics and automated optical sorting systems.
The role of data
Another crucial technology transforming MRF operations is data analytics. Real-time data improves operational efficiency by tracking waste streams, optimizing processes, and maximizing resource recovery.
Historically, MRF operators relied on retrospective, manual analysis, essentially looking at yesterday’s data to fix today’s problems. Real-time monitoring changes that. Citing the example of Tomra’s Waste Analyzer, powered by PolyPerception, Tasos Bereketidis, VP Sales, Emerging Markets, Tomra, noted that AI waste analytics platforms give operators instant visibility into material composition trends, removing the traditional reliance on guesswork.”
“This enables yield losses, mis-sorts, and quality deviations to be identified the moment they occur. Operators can now compare performance across different shifts and lines using live data, allowing much faster root-cause analysis when throughput or quality fluctuates.”
Decision-making has moved from experience-based assumptions toward precise, data-driven adjustments on the plant floor, he pointed out.
Vikram Shrinivas, MRF Plant Manager, Dulsco Environment, explained how connected data collection architecture helps monitor operational metrics across the entire waste processing workflow at Dulsco’s MRF. The weighbridge system serves as the primary intake measurement point, recording net tonnage of incoming commingled recyclable streams in real time. This baseline metric is critical for understanding processing capacity utilization and waste flow dynamics.
Further along the process, conveyor line weighing scales track the movement of materials through each sorting stage, providing detailed, material-specific throughput data. This secondary layer of data capture allows operators to monitor how waste progresses between units, such as from the bag-opening station to the trommel, ensuring precise measurement at each step. The baler adds a tertiary layer, recording the number of bales produced and the quantities of each material category. “This real-time output data helps assess overall recovery performance and sorting efficiency, offering valuable insights into both the quantity and quality of recyclables successfully recovered at every stage of the process,” he added.
He highlighted how data-driven decision-making has significantly improved operational efficiency at the facility. “It optimizes processing capacity, improves resource allocation, and enhances material recovery. Real-time data allows operators to balance waste intake, plan maintenance proactively, and quickly resolve sorting inefficiencies. These insights help reduce downtime, improve recovery quality, and maximize plant performance.”
At FARZ MRF, real-time data on inbound and outbound waste streams is generated through a combination of digital weighing systems, automated process controls, and sensor-based sorting technologies.
According to Safeyeldin, all incoming waste vehicles are routed through weighbridges integrated with centralized data management platforms, allowing precise tracking of waste quantities by source, stream (MSW or C&I), and time of delivery.
Inside the facility, automated conveyors, shredders, trommels, and separators are digitally monitored to provide continuous visibility on material flow and system performance. Optical sorting units employing near-infrared sensors and machine vision generate high-resolution data on plastics, paper, metals, and residual waste fractions, he expounded. Outbound streams are similarly monitored: recovered materials like HDPE, PET, ferrous and non-ferrous metals, OCC, wood, and PE films are weighed, baled, and digitally logged before dispatch. “This enables accurate reporting of recovery rates, contamination levels, and carbon-reduction metrics, supporting regulatory compliance and ESG reporting.”
Bereketidis threw light on a cloud-based sorting data platform, Tomra Insight, which expands the focus beyond mere tonnage to include purity, yield, and sorting efficiency, providing transparency on where value is created or lost along the sorting line. “Integrating detailed waste analysis gives operators a granular view of material composition at strategic points, supporting more informed commercial and operational decisions,”
“In regions where input quality varies, these insights help operators prioritise quality-driven optimisation,” he noted.
AI and deep learning in sorting
By combining AI with real-time data, MRFs are moving from volume-based metrics to quality and value metrics, optimizing yield, purity, and sorting efficiency even in heterogeneous waste streams. Using such tools, operators can proactively identify deviations, prioritize high-value materials, and make rapid, data-driven adjustments on the plant floor.
AI and deep learning should be viewed as an extension of proven sensor-based sorting, not a replacement, Bereketidis said, adding, “In markets like the Middle East, where source segregation can be variable, AI waste analytics platforms help shift focus from throughput to quality-driven output.”
He went on to highlight the potential of AI-powered deep learning technology. “Our deep learning technology GAINnext, for instance, can add value where traditional sensors reach their limits, particularly visually complex material differences rather than chemical or spectral differences.” It uses RGB cameras to see what the human eye sees, and more. While successful globally in packaging, wood and metal, it is adaptable and trainable for Middle Eastern streams, offering clear potential for regional MRFs, he noted.
Challenges in the Middle East
The Middle East presents specific challenges, from high temperatures and dust to highly variable input material. “Technologically, deep learning systems like GAINnext is trained in-house by our experts to adapt to local waste streams. Furthermore, a strong local service network that understands the region’s specific needs remains vital for maintaining uptime.”
A robust regional service network ensures system uptime, complementing hardware designed to withstand high temperatures, dust, and variable waste composition.
Challenges in Automation
Despite clear advantages, implementing advanced automation systems in MRFs presents challenges.
Safeyeldin highlighted that the high capital and maintenance cost of optical sorters, AI software, and robotics are key challenges, particularly in harsh regional operating conditions characterized by heat, dust, and variable waste composition. “Waste heterogeneity is another challenge: low levels of source segregation in the Middle East mean waste streams are often heavily contaminated. While automation improves efficiency, poor upstream segregation can limit expected gains from AI-based sorting.”
Operationally, skilled technicians, data analysts, and software integration capabilities remain scarce, he noted. “Studies on AI adoption in the GCC highlight that technology readiness often outpaces workforce and organizational readiness, delaying full value realization. Consequently, certain processes, such as final quality control or handling complex composite materials, still rely on manual intervention, as automation has yet to deliver complete efficiency gains.”
Shrinivas also highlighted the challenges from contamination in mixed waste stream. He opined that integration with existing equipment, occasional data inconsistencies, and the need for continuous staff training are key hurdles. “Maintenance downtime and contamination in mixed waste streams can reduce automation efficiency, as heavily contaminated loads still require manual intervention.” In some stages, automation cannot fully adapt to varying material quality, meaning efficiency gains continue to improve as systems and processes are refined, he pointed out.
The future of MRFs
The future lies in ‘adaptive MRFs’, Bereketidis predicted. “We expect greater integration through intuitive sorter control software systems like TOMRA Local Control, which enables operators to manage multiple sorters centrally and react faster to changing conditions.
We are moving away from reactive operations toward continuous, data-driven optimisation.”
On a global level, deep learning can automate visually complex tasks that previously required manual sorting. For the Middle East, the focus will be on total operational transparency to manage mixed waste streams more effectively and maximise value recovery, he further added.
Speaking from an operator perspective, Safeyeldin remarked that advanced AI and machine learning models capable of adapting to highly mixed waste streams will be critical, particularly those that go beyond visual identification and analyse material properties in real time.
“End-to-end digital traceability, enabled by IoT sensors, RFID tagging, and integrated data platforms, will also play a major role. These systems allow waste to be tracked from collection through processing and final reuse, supporting regulatory transparency and circular economy reporting.” He also highlighted the role of robotic sorting systems with self-learning capabilities, coupled with predictive maintenance powered by AI, to reduce downtime and lifecycle costs.
The integration of MRFs with waste-to-energy and refuse-derived fuel systems, supported by digital optimization tools, will also be crucial for handling residual waste streams sustainably in land-constrained cities like Dubai, he noted.
Shrinivas noted that facilities must also adopt smart data systems such as predictive maintenance, SCADA (Supervisory Control and Data Acquisition) and real-time analytics to minimise downtime and optimise performance.
“Equally important are technologies designed for the region’s hot summer climate, including heat-resilient equipment, smart cooling and dust control systems and automation that reduces manual exposure to extreme temperatures.”
Circular-economy integration through material traceability, marketplace connectivity and flexible sorting systems will help UAE MRFs handle diverse waste streams and strengthen recycling markets across the region, he observed.
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