Studio di fattibilità di un impianto di condizionamento tramite sistema geotermico: il caso ospedale nuovo di Imola

L’obiettivo dell’elaborato è analizzare la fattibilità tecnica ed economica di un impianto di prelievo d’acqua da falda artesiana per lo scambio termico nell’impianto frigorifero centralizzato dell’ospedale civile nuovo di Imola. Esso provvede a fornire acqua refrigerata a tutte le unità di trattamento aria (u.t.a.) del complesso ospedaliero ed è finalizzato a garantire per ogni locale le specifiche condizioni igrometriche , nonchè il benessere degli operatori e dei pazienti della struttura. Il lavoro di progettazione ha riguardato il dimensionamento di componenti e reti idrauliche con l’ausilio del software “EPANET” (programma per la simulazione di reti idrauliche). L’idea che ha guidato il presente elaborato è stata la creazione di un “ciclo” dell’acqua tale per cui l’acqua di scarto delle torri evaporative viene utilizzata per l’irrigazione degli orti nei pressi dei quale sorge il pozzo e successivamente, va ad alimentare la falda stessa. Le scelte progettuali hanno quindi dovuto considerare questo importante vincolo e sono state tese alla minimizzazione dei consumi d’acqua e , quindi, alla sostenibilità ambientale dell’intero impianto. In generale, infatti non è detto che la soluzione economicamente più vantaggiosa lo sia anche dal punto di vista ambientale. La soluzione adottata con rilancio dell’acqua agli orti limita il prelievo medio giornaliero d’acqua di falda di 20 m3/gg durante il periodo estivo. E’stato dimostrato come il progetto sia tecnicamente fattibile e generi valore per l’impresa con indice di rendimento IR(VAN/Capitale investito) pari a 1,29 per i primi 20 anni e pari a 2,06 per n anni di funzionamento dell’impianto con un tempo di recupero del capitale investito pari a sei anni.

A multi-objective genetic algorithm optimisation using variable speed pumps in water distribution systems

Due to its practical importance and inherent complexity, the optimisation of distribution networks for supplying drinking water has been the subject of extensive study for the past 30 years. The optimization is governed by sizing the pipes in the water distribution network (WDN) and / or optimises specific parts of the network such as pumps, tanks etc. or try to analyse and optimise the reliability of a WDN. In this thesis, the author has analysed two different WDNs (Anytown City and Cabrera city networks), trying to solve and optimise a multi-objective optimisation problem (MOOP). The main two objectives in both cases were the minimisation of Energy Cost (€) or Energy consumption (kWh), along with the total Number of pump switches (TNps) during a day. For this purpose, a decision support system generator for Multi-objective optimisation used. Its name is GANetXL and has been developed by the Center of Water System in the University of Exeter. GANetXL, works by calling the EPANET hydraulic solver, each time a hydraulic analysis has been fulfilled. The main algorithm used, was a second-generation algorithm for multi-objective optimisation called NSGA_II that gave us the Pareto fronts of each configuration. The first experiment that has been carried out was the network of Anytown city. It is a big network with a pump station of four fixed speed parallel pumps that are boosting the water dynamics. The main intervention was to change these pumps to new Variable speed driven pumps (VSDPs), by installing inverters capable to diverse their velocity during the day. Hence, it’s been achieved great Energy and cost savings along with minimisation in the number of pump switches. The results of the research are thoroughly illustrated in chapter 7, with comments and a variety of graphs and different configurations. The second experiment was about the network of Cabrera city. The smaller WDN had a unique FS pump in the system. The problem was the same as far as the optimisation process was concerned, thus, the minimisation of the energy consumption and in parallel the minimisation of TNps. The same optimisation tool has been used (GANetXL).The main scope was to carry out several and different experiments regarding a vast variety of configurations, using different pump (but this time keeping the FS mode), different tank levels, different pipe diameters and different emitters coefficient. All these different modes came up with a large number of results that were compared in the chapter 8. Concluding, it should be said that the optimisation of WDNs is a very interested field that has a vast space of options to deal with. This includes a large number of algorithms to choose from, different techniques and configurations to be made and different support system generators. The researcher has to be ready to “roam” between these choices, till a satisfactory result will convince him/her that has reached a good optimisation point.