[{"data":1,"prerenderedAt":113},["ShallowReactive",2],{"activity-en-5.3":3,"sector-for-en-5.3":86},{"id":4,"title":5,"activityCode":6,"activityType":7,"body":8,"description":68,"dnsh":69,"extension":74,"meta":75,"naceCodes":76,"navigation":78,"path":79,"sector":80,"seo":81,"stem":82,"substantialContribution":83,"__hash__":85},"activities_en\u002Fen\u002Fsectors\u002Fwater-and-waste\u002Factivities\u002F5-3-wastewater-systems.md","Construction, Extension and Operation of Waste Water Collection and Treatment","5.3","standard",{"type":9,"value":10,"toc":58},"minimark",[11,16,20,23,27,30,34,37,41,44,48,51,55],[12,13,15],"h2",{"id":14},"substantial-contribution-to-climate-change-mitigation","Substantial Contribution to Climate Change Mitigation",[17,18,19],"p",{},"The wastewater treatment plant must achieve an energy consumption at or below 35 kWh per population equivalent per year for plants above 10,000 p.e., or demonstrate at least a 20% improvement in energy efficiency compared to the prior baseline. Energy recovery from the treatment process (biogas from anaerobic sludge digestion) must be maximised, with recovered energy covering at least 50% of the plant's total energy demand where technically feasible.",[17,21,22],{},"Direct GHG emissions from the treatment process, including methane and nitrous oxide, must be monitored and minimised through process optimisation. Where the plant serves more than 100,000 p.e., a carbon footprint assessment covering Scope 1 and Scope 2 emissions must be completed.",[12,24,26],{"id":25},"substantial-contribution-to-climate-change-adaptation","Substantial Contribution to Climate Change Adaptation",[17,28,29],{},"The infrastructure must be assessed for physical climate risks under Appendix A, covering increased stormwater loads, flood exposure, temperature effects on biological treatment processes, and sea level rise for coastal installations.",[12,31,33],{"id":32},"dnsh-climate-change-adaptation","DNSH: Climate Change Adaptation",[17,35,36],{},"Climate hazards must be assessed per Appendix A. The design must incorporate overflow management, flood protection for critical electrical equipment, and thermal resilience for biological treatment stages.",[12,38,40],{"id":39},"dnsh-water-and-marine-resources","DNSH: Water and Marine Resources",[17,42,43],{},"Effluent quality must meet or exceed the requirements of the Urban Waste Water Treatment Directive (91\u002F271\u002FEEC), including nutrient removal standards for sensitive areas. The discharge must not cause deterioration of receiving water body status under the Water Framework Directive.",[12,45,47],{"id":46},"dnsh-circular-economy","DNSH: Circular Economy",[17,49,50],{},"Sludge must be managed as a resource, with recovery of nutrients (phosphorus, nitrogen) or energy prioritised. At least 70% of non-hazardous construction waste must be prepared for re-use or recycling.",[12,52,54],{"id":53},"dnsh-pollution-prevention-and-control","DNSH: Pollution Prevention and Control",[17,56,57],{},"Odour and noise from the facility must be controlled using Best Available Techniques. Combined sewer overflows must be minimised through storage capacity or real-time control systems. Micropollutant removal should be considered for plants in sensitive catchments.",{"title":59,"searchDepth":60,"depth":60,"links":61},"",2,[62,63,64,65,66,67],{"id":14,"depth":60,"text":15},{"id":25,"depth":60,"text":26},{"id":32,"depth":60,"text":33},{"id":39,"depth":60,"text":40},{"id":46,"depth":60,"text":47},{"id":53,"depth":60,"text":54},"Construction and operation of wastewater collection and treatment systems that meet or exceed Urban Waste Water Treatment Directive requirements with optimised energy performance.",[70,71,72,73],"cca","water","ce","pp","md",{},[77],"E37.00",true,"\u002Fen\u002Fsectors\u002Fwater-and-waste\u002Factivities\u002F5-3-wastewater-systems","water-and-waste",{"title":5,"description":68},"en\u002Fsectors\u002Fwater-and-waste\u002Factivities\u002F5-3-wastewater-systems",[84,70],"ccm","6rFsWz9-Pci5x9BOES8dc7axRbMk_ZkxB5RfDJOTFFQ",{"id":87,"title":88,"activityCount":89,"body":90,"description":103,"extension":74,"icon":104,"meta":105,"naceCodeRange":106,"navigation":78,"objectives":107,"path":108,"sectorNumber":109,"seo":110,"stem":111,"__hash__":112},"sectors_en\u002Fen\u002Fsectors\u002Fwater-and-waste.md","Water Supply, Sewerage & Waste",6,{"type":9,"value":91,"toc":101},[92,95,98],[17,93,94],{},"Water supply, sewerage, and waste management form a critical infrastructure sector in the EU Taxonomy. These activities are essential for public health and environmental protection, and they present significant opportunities for reducing emissions and advancing circular economy goals.",[17,96,97],{},"The sector includes water collection and treatment, construction and operation of wastewater treatment plants, anaerobic digestion of sewage sludge and bio-waste, material recovery from non-hazardous waste, and landfill gas capture. Each activity has specific criteria targeting energy efficiency, methane emission reduction, and resource recovery rates.",[17,99,100],{},"Climate adaptation is particularly important for water and waste infrastructure, which is highly exposed to physical climate risks. Flooding can overwhelm sewerage systems, drought affects water supply, and extreme heat accelerates waste decomposition. The Taxonomy requires operators to assess these risks using forward-looking climate scenarios and implement infrastructure upgrades or operational adjustments to maintain service reliability under changing conditions.",{"title":59,"searchDepth":60,"depth":60,"links":102},[],"Water treatment, waste management, and resource recovery activities supporting circular and clean systems.","lucide:droplets",{},"E36-E39",[84,70,72],"\u002Fen\u002Fsectors\u002Fwater-and-waste",5,{"title":88,"description":103},"en\u002Fsectors\u002Fwater-and-waste","iZi0ZvbAh1RNi-NzbdLIuk0V26l8mO_Vi24CSyVRHxU",1775591374204]