SYNERGIA 9n1 Climate-Resilient Cooling System

The Synergia 9n1 initiative addresses the critical challenges of extreme heat, high energy consumption, and indoor air pollution in regions like Qatar and the broader MENA region, where temperatures frequently exceed 40°C. Conventional air conditioning systems are energy-intensive and emit substantial indirect greenhouse gases, contributing to climate change. Additionally, these systems often fail to provide sufficient fresh air circulation, exacerbating indoor air pollution and related health risks. With over 48% of the global population facing extreme heat annually, there is an urgent need for innovative, low-carbon cooling solutions that also enhance air quality. The Synergia 9n1 system is designed to tackle these issues by improving energy efficiency, reducing emissions, and providing 100% fresh air circulation.

The Synergia 9n1 initiative by GORD is designed to address the pressing challenges of extreme heat, high energy demands, and indoor air pollution, particularly in the MENA region. Its goal is to provide a sustainable cooling solution that reduces indirect greenhouse gas emissions, improves indoor air quality, and lessens the health risks associated with air pollution. By focusing on SDG 13 (Climate Action), SDG 3 (Good Health and Well-being), and SDG 7 (Affordable and Clean Energy), the project aims to demonstrate how innovative technologies can make a measurable impact on climate resilience and public health. The initiative employs a unique, multimodal cooling system that integrates three advanced cooling technologies (desiccant dehumidification, indirect evaporative cooling, and adiabatic condenser cooling) with six energy-harvesting techniques (refrigerant desuperheating, waste heat recovery, desiccant heat rejection, adiabatic cooling, condensate water reuse, VFD condenser fans modulation This combination enables Synergia 9n1 to reduce energy consumption by up to 50% compared to conventional outdoor air cooling systems known as (DOAS). By its ability to cool efficiently 100% outdoor air, it can be used to cool or climatize the outdoor and semi enclosed spaces contributing to increased wellbeing and health by providing opportunities for people to spend more times outdoor in addition to significantly enhancing the indoor air quality —a critical factor in reducing respiratory health issues. The collaborative process involved multiple stakeholders, including funding from Qatar National Research Fund and technical support from the Supreme Committee for Delivery and Legacy, establishing a robust partnership structure that leverages regional expertise. Synergia 9n1 has led to cross-country knowledge sharing between various countries in the South(receiving an award for Best Patent in Energy Efficiency from the League of Arab States), especially those facing extreme climate conditions. This initiative exemplifies South-South cooperation by developing a scalable, energy-efficient technology that can be adapted to other regions with similar climates, advancing the common goal of mitigating the adverse impacts of climate change. The outcomes of the initiative reflect a substantial contribution to SDG targets: energy use is cut nearly in half, and with a Coefficient of Performance (COP) up to 5, Synergia 9n1 is among the most efficient cooling systems available. Quantitatively, these features contribute directly to achieving the SDG targets by reducing indirect CO? emissions and enhancing energy efficiency in urban infrastructure. Synergia 9n1’s innovation lies in its climate-adaptive technology, designed to be responsive to a variety of ambient weather conditions. This adaptability gives it a competitive edge by enabling widespread applicability, from hospitals and clean rooms to greenhouses and temporary facilities, where conventional air conditioning is impractical. The technology’s emphasis on automation and user-friendly design ensures sustained benefits over the long term, with low maintenance costs and the potential for climate policy integration that supports sustainable cooling solutions. The replicability of Synergia 9n1 is clear, with potential applications in multiple regions requiring climate-smart technology. It can be adapted to similar hot and humid climates, provided that rudimentary air conditioning infrastructure and expertise are in place to implement and maintain the system. Lessons learned include the importance of integrating multiple cooling methods to maximize efficiency, the need for strong partnerships to drive innovation, and the value of designing adaptable solutions that meet specific environmental needs while ensuring user accessibility and long-term sustainability.