Dataset Supporting Deliverable 1.5 - New approaches and best practices for closing the material cycles within symbiosis cluster

Dataset containing the data the support the experimental findings described in ULTIMATE delivarable 1.5. This deliverable is available on Zenodo under https://doi.org/10.5281/zenodo.14967803  In concerns the following: Case Study 3 (Rosignano, Italy) - Use of by-products of local industries for wastewater treatment in Rosignano Table 3.1. Design parameters of the adsorption columns. Figure 3.1. Dose curve of the AOP Pilot Plant Table 3.2. Hardness and COD removal during laboratory tests. Figure 3.2 Conductivity values in the inlet and outlet streams Figure 3.3 pH values in the inlet and outlet streams. Figure 3.4 Alkalinity values in the inlet and outlet streams. Figure 3.5 CO3- concentration values in the inlet and outlet streams. Figure 3.6 HCO3- concentration values in the inlet and outlet streams. Figure 3.7 OH- concentration values in the inlet and outlet streams. Figure 3.8 Temporary and permanent hardness removal Figure 3.9 Hardness removal efficiency. Table 3.3. Results of Jar Test experiments using coagulant solution recovered from aluminium sludge Table 3.4. General characteristics of the activated carbon used Figure 3.10 Breakthrough curve of UV254 and fluorescence signal from real-time sensors during adsorption Test 1. Figure 3.11 Breakthrough curve of UV254 and fluorescence signal from real-time sensors during adsorption Test 2. Figure 3.12 Breakthrough curve of carbamazepine and primidone during the two adsorption experimental tests Table 3.5. Observed correlation between spectroscopic sensors’ signals and monitored emerging contaminants Figure 3.13 Observed correlation between sulfamethoxazole and fluorescence during adsorption Test 2. C0 and F0 are observed concentration of the contaminant and fluorescence signal in the influent, respectively Figure 3.14 Fluorescence spectra of the wastewater influent to the AOP pilot plant collected at different days Figure 3.15 Fluorescence signal of the influent and effluent of the AOP pilot plant recorded in real-time Figure 3.16 Observed concentrations of primidone and clarithromycin in the influent (blu indicator) and effluent (orange indicator) of the AOP pilot plant Figure 3.17 Correlation analysis between fluorescence removal and emerging contaminants removal during AOP process Table 3.6. Observed correlations between removal of fluorescence signal and organic micropollutants during AOP process   Case Study 6 (Karmiel, Israel) - Recovery of high-value products from olive mill wastewater   Figure 6.1 Polyphenols concentration of the raw OMW and the OMW after the different adsorption runs Figure 6.2 The reuse of methanol for extracting the adsorbed polyphenols on the resin for six successive runs. Figure 6.3 (A) corresponds to the system with 2.5% of OMW mixed with synthetic wastewater, and on (B) corresponds to 2.5% of treated OMW by the resin bed. Figure 6.4 a) the effect of extraction of polyphenol from OMW othe methane yield of the the mixed OMW with domestic WW. (b) the effect of polyphenol extraction on its removal by the anaerobic biodegradation.  Figure 6.5 Total COD of in and out of the AAT as a result of the extraction process of polyphenol by the resin. Figure 6.6 Soluble COD of in and out of the AAT as a result of the extraction process of polyphenol by the resin. Figure 6.7 The effect of polyphenol extraction on the removal of polyphenol after the anaerobic (AAT) treatment Figure 6.8 The effect of polyphenol extraction on the biogas rate Figure 6.9 The effect of polyphenol extraction on the average biogas production rate.    Case Study 7 (Tain, UK) - Recovery of nutrients from distillery wastewater after AnMBR treatment in Tain Figure 7.1 Examples of X-ray diffraction spectra of the products recovered at pHs of (a) 7.4, (b) 7.7, (c) 8.1 and (d) 8.9. Table 7.1 Metals and COD content of the products recovered at different pHs as % mass. Figure 7.2 Impact of pH on the performance of the ammonia stripping unit. Figure 7.3 Impact of N/metal ratio on ammonia stripping efficiency (lab-scale trials with synthetic solutions) Figure 7.4 Evolution of the ammonia concentration over time for an example of a single batch of the acid solution in the scrubber.   Case Study 8 (Roussillon, France) - Recovery of sulphur at the Chemical Platform Roussillon Table 8.1: Testing conditions Table 8.2: Typical ranges for operating parameters during the pilot tests Figure 8.1: Results obtained in the evolution of SO2 content between each operation unit of the pilot Table 8.3: Best results obtained in the pilot. Figure 8.2: Evolution of metals in the NaHSO3 solution Figure 8.3: Evolution of halogens in the NaHSO3 solution Figure 8.4: Adsorption efficiency obtained during lab tests at different temperatures Figure 8.5: Adsorption efficiency of the pilot at different pH Figure 8.5: Adsorption yield results of the pilot modelling, comparison with experimental results   Case Study 8 (Roussillon, France) - Recovery of metals Table 8.4: description of the ion exchange resins tested Figure 8.6: Results on 10-fold diluted effluent for resin A Table 8.5: Results on 10-fold diluted effluent for resin A Figure 8.7: Comparison of results for a 10-fold and 5-fold diluted effluent for resin A Table 8.6: Results on 5-fold diluted effluent for resin A Figure 8.8: Comparison of results for 10-, 5- and 3-fold diluted effluent for resin A Figure 8.9: Comparison of results on resin A with and without preconditioning Table 8.7: Results with and without conditioning for resin A Figure 8.10: Influence of the resin A quantity / effluent quantity ratio on molybdenum absorption efficiency for 3-fold diluted effluent Figure 8.11: Comparison of results obtained on different resins Table 8.8: Results of elution lab tests Table 8.9: Results of lifetime lab tests   Case Study 9 (Kalundborg, Denmark) - I2.9. Concept study for nutrient and/or high-value product recovery in Kalund Table 9.1: No. of samples, mean, median, min, max and variance of various parameters in the concentrate of the NF-RO scheme in CS9 measured by the iWWTP Table 9.2: Influent loads within the iWWTP (industrial waste water treatment plant), the conc. (concentrate under study), ratio of concentrate in total load, potential recovery rate in concentrate and related to iWWTP influent