{"id":26189,"date":"2025-07-03T11:31:24","date_gmt":"2025-07-03T03:31:24","guid":{"rendered":"https:\/\/www.robustel.com\/?p=26189"},"modified":"2025-07-04T08:02:10","modified_gmt":"2025-07-04T00:02:10","slug":"smart-water-management-turkey-gsl-robustel-r1511","status":"publish","type":"post","link":"https:\/\/www.robustel.com\/de\/case-study\/smart-water-management-turkey-gsl-robustel-r1511\/","title":{"rendered":"Empowering Smart Water Management Systems in Turkey: How GSL Delivers Resilient Remote Monitoring with the Robustel R1511."},"content":{"rendered":"\n\n\t\t\t\t\"Empowering\n\t

Smart Water Management Systems at Work: GSL and Robustel Empower Turkey’s Water Infrastructure<\/strong><\/h4>\n\t

Water is a strategically vital resource in Turkey-economically, ecologically, and geopolitically. From the drought-sensitive central Anatolian plains to the snow-laden highlands of Kars, managing this resource effectively is a national imperative. As the country accelerates its digital transformation agenda, nowhere is the need for robust, real-time infrastructure more visible than in water quality monitoring.<\/p>\n

Since 2014, GSL<\/b><\/a>, a leading IoT integrator in Turkey, has partnered with Robustel to deliver innovative connectivity solutions across energy, utilities, and critical infrastructure. Their latest collaboration focuses on deploying Smart Water Management Systems<\/b> in coordination with Turkey’s top water authorities: the General Directorate of Meteorology (MGM), the Ankara Water and Sewerage Administration (ASKI), and the State Hydraulic Works (DSI).<\/p>\n

At the heart of this project is a need for reliable, scalable, and field-ready IoT connectivity. These agencies are moving beyond reactive models-introducing sensor-based systems that collect real-time data across basins, reservoirs, and remote mountain sites. Backed by SCADA platforms and cellular telemetry, this infrastructure helps ensure environmental sustainability, public health, and national compliance with global water governance standards.<\/p>\n\t

Business Challenge 1: Diverse Terrains, Makes Connectivity A Problem<\/strong><\/h4>\n\t

Turkey’s geography is stunning-but brutal for environmental infrastructure. In Ankara, water basins sprawl across semi-arid lowlands, requiring sensors to be deployed across vast, hard-to-reach distances. In contrast, the Kars region in the northeast experiences extreme winter conditions, with snow and ice covering high-altitude reservoirs for months at a time. These vastly different conditions created logistical and environmental barriers for deploying water quality monitoring systems.<\/p>\n

Sensor nodes were installed on buoys floating in remote reservoirs-some only accessible by boat-while others were placed at altitude on rugged terrain. In both scenarios, technicians had limited access for setup, calibration, or maintenance. Traditional cabling for power or data was out of the question. The systems needed to be 100% autonomous, climate-resilient, and capable of operating for long periods without physical intervention.<\/p>\n

This diversity in deployment sites meant that a one-size-fits-all approach was impossible. The solution needed to adapt to both mobility on water and harsh topography on land, without sacrificing performance. For Turkey’s public water agencies, ensuring nationwide consistency in water quality monitoring demanded a solution that was flexible, rugged, and technically fit for both extremes.<\/p>\n\t\t\t\t\"Environmental\n\t\tWater Sensor nodes installed on buoys floating in remote reservoirs\n\t

Business Challenge 2: GSM Dead Zones Threaten Data Continuity<\/strong><\/h4>\n\t

Consistent data transmission is the foundation of modern water management-but it’s also the first thing to fail in hard-to-reach environments. Across Kars and other remote Turkish provinces, GSM signal quality ranged from weak to non-existent. Even in Ankara, known for its infrastructure investment, many basins and reservoirs fell into coverage dead zones or zones with unstable bandwidth.<\/p>\n

This presented a critical challenge for the real-time SCADA platforms used by MGM, ASKI, and DSI. Inconsistent signal meant delayed or missing sensor data-undermining the agencies‘ ability to detect contamination events, monitor pH or conductivity shifts, or comply with real-time reporting obligations. In practical terms, the system couldn’t be trusted to always „see“ what was happening in the field.<\/p>\n

Conventional routers lacked the network resilience to adapt. With no support for multi-network SIMs or intelligent failover, these devices either stalled when a signal dropped or required manual intervention to reset. This was unacceptable for a system expected to run 24\/7, often unattended.<\/p>\n

For the project to succeed, connectivity had to be not just available-but self-sustaining, adaptive, and intelligent enough to maintain uptime in the face of unstable infrastructure.<\/p>\n\t\t\t\t\"Smart\n\t\tRemote Monitoring Stations sometimes situated on the fringe of connectivity\n\t

Business Challenge 3: Power Isn’t a Given<\/strong><\/h4>\n\t

Unlike smart infrastructure in cities, rural and mountainous monitoring stations often operate far from grid power. That was the case across much of the Turkish deployment zone-where both buoy-mounted sensors and hilltop PLCs had to rely entirely on off-grid solutions like solar panels and battery packs.<\/p>\n

The problem wasn’t just the absence of grid access-it was that earlier communications hardware simply couldn’t cope with the energy constraints. Devices consumed too much power or had poor battery management, forcing premature outages during long winter stretches when solar generation dropped dramatically.<\/p>\n

Reliability suffered. Sensor nodes that lost power stopped sending data, disrupting environmental reporting and forcing agencies to dispatch field teams for troubleshooting. These visits were costly, slow, and-during bad weather-sometimes impossible. In remote basins, one failure could leave a critical data blind spot for weeks or even months.<\/p>\n

Any viable solution needed to operate continuously on minimal power, tolerate variable solar input, and extend battery life as far as possible. Without this, even the best data acquisition systems would be useless in the field. Power resilience was not just a feature; it was a core operational requirement.<\/p>\n\t\t\t\t\"Smart\n\t\tMonitoring stations in remote locations powered via battery and solar\n\t\t\t\t\"Robustel-&-GSL-Water-Monitoring-CS-Diagram\"\n\t

Smart Water Management System – Solution Overview<\/strong><\/h4>\n\tAfter a thorough evaluation of environmental, technical, and operational constraints, Turkish technology integrator GSL selected Robustel’s R1511 router as the backbone of the communication infrastructure. Compact, robust, and purpose-built for industrial deployments, the R1511 delivered on every requirement for Turkey’s water monitoring modernization project.\n

Why GSL chose the Robustel R1511?<\/strong><\/p>\n