Investigation of temporal mismatch of the energy consumption and local energy generation in the domestic environment

Qaryouti, Ghazi

January 2014

Conventional energy sources are not only finite and depleting rapidly, but are a major source of global warming because they are key contributors of greenhouse gases to the atmosphere. Renewable energy sources are one important approach to these challenges. Distributed micro-generation energy sources are expected to increase the diversity of energy sources for the grid, but also increase the flexibility and resilience of the grid. Furthermore, it could reduce the domestic energy demand from the grid by enabling local consumption of energy generated through renewable sources. The most widely installed renewable energy generation systems in domestic environments, in UK, are based on solar power. However, there is a common recurring issue related to output intermittency of most promising renewable energy generation methods (e.g. solar and wind), resulting in a temporal energy mismatch between local energy generation and energy consumption. Current state-of-the-art technologies/solutions for tackling temporal energy mismatch rely on various types of energy storage technologies, most of which are not suitable for the domestic environments because they are designed for industrial scale application and relatively costly. As such energy storage system technologies are generally not deemed as economically viable or attractive for domestic environments. This research project seeks to tackle the temporal energy mismatch problem between local PV generated energy and domestic energy consumption without the need for dedicated energy storage systems; without affecting the householders comfort and/or imposing operational burdens on the householders. Simulation has been chosen as the major vehicle to facilitate much of the research investigation although data collated from related research projects in the UK and Jordan have been used in the research study. Solar radiation models have been established for predicting the solar radiation for days with clear-sky for any location at any time of the year. This model has achieved a correlation factor of 0.99 in relating to the experimental data-set obtained from National Energy Research Centre Amman/Jordan. Such a model is an essential component for supporting this research study, which has been employed to predict the amount of solar power that could be obtained in different locations and different day(s) of the year. A Domestic Energy Ecosystem Model (DEEM) has been established, which is comprised of two sub-models, namely “PV panels” and “domestic energy consumption” models. This model can be configured with different parameters such as power generation capacity of the photovoltaic (PV) panels and the smart domestic appliances to model different domestic environments. The DEEM model is a vital tool for supporting the test, evaluation and validation of the proposed temporal energy mismatch control strategies. A novel temporal energy mismatch control strategy has been proposed to address these issues by bringing together the concepts of load shifting and energy buffering, with the support of smart domestic appliances. The ‘What-if’ analysis approach has been adopted to facilitate the study of ‘cause-effect’ under different scenarios with the proposed temporal energy mismatch control strategy. The simulation results show that the proposed temporal energy mismatch control strategy can successfully tackle the temporal energy mismatch problem for a 3 bedroom semi-detached house with 2.5kWp PV panels installed, which can utilise local generated energy by up to 99%, and reduce the energy demand from the grid by up to 50%. Further analysis using the simulation has indicated significant socio-economic impacts to the householders and the environment could be obtained from the proposed temporal energy mismatch control strategy. It shows the proposed temporal energy mismatch control strategy could significantly reduce the annual grid energy consumption for a 3 bedrooms semi-detached house and produce significant carbon reductions.

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Mathematical simulation and optimization of a stand alone zero emissions hybrid system based on renewable energy sources / Μαθηματική προσομοίωση και βελτιστοποίηση μιας υβριδικής αυτόνομης μηδενικών ρύπων μονάδας παραγωγής ηλεκτρικής ενέργειας που τροφοδοτείται αποκλειστικά από ΑΠΕ

Προδρομίδης, Γεώργιος

01 August 2014

Renewable Energy Sources (RES) are the most promising resources of energy production for everyday life. Therefore, the precise combination of RES based technologies into hybrid systems could provide the solution to several energy problems facing the planet. The motivation of the present research study is the total understanding of the prevailing phenomena by using RES equipment in several projects. This thesis will focus on standalone hybrid RES based systems. By presenting the RES systems the necessity of buffering systems will become apparent as the most crucial parts of off-grid systems. Therefore, the most well-established buffering technologies will be analytically presented in order to be subsequently embodied into the simulated RES applications. Following the above theoretical approach of RES based equipment and hybrid systems in general, this thesis will focus on a more applied research study comprising the energetic and economical simulation and optimization of a RES based stand alone system that is already installed in Leicestershire, UK. Based on local meteorological data, an optimization strategy has been developed to identify the most economical and efficient scenarios for electricity generation to cover the desirable load on an annual basis. Furthermore, the environmentally-friendly character of the system was highly concerned with emissions reduction; therefore the capability of an off-grid system was also investigated. The feasibility of RES based systems for electricity supply will then be presented for four different Greek Islands. Three specific typical loads have been selected to be covered and the grid connection was considered optional. Up to this point the simulation and optimization procedures were applied by using the HOMER software tool in order to investigate the most suitable well-established platform in the world. After the theoretical research study on the most well-known platform of HOMER an innovative optimization theory based on the energy part of a hybrid system will be presented in order to select the most efficient system according to the desired requirements and the location of a RES based project. This thesis will then focus on the design and operation of an autonomous hybrid system under real-life meteorological conditions which is capable of simulating several loads assumed to cover the electricity demands of small buildings. The specific hybrid system embodies technologies that use photovoltaic and wind energy in combination with an electrochemical storage bank. Experiments on the coverage of annual loads regarding a typical house, a typical country house and a small company were also performed to prove the feasibility of the stand-alone system. The same established RES project was then simulated on a yearly basis using the HOMER software platform to determine real-time results. The above analysis revealed that HOMER software cannot successfully simulate the operation of such a system, therefore the design of a new mathematical model to produce results similar to those of the experimental process was considered essential based on a new optimization strategy. / Οι Ανανεώσιμες Πηγές Ενέργειας (ΑΠΕ) αποτελούν τις πιο πολλά υποσχόμενες πηγές στον τομέα της παραγωγής της ηλεκτρικής ενέργειας μέσα στην ανθρώπινη καθημερινότητα. Έτσι ο ακριβής συνδυασμός των ΑΠΕ σε υβριδικά συστήματα θα μπορούσε να αποτελέσει τη λύση στο μεγάλο ενεργειακό πρόβλημα που αντιμετωπίζει ο πλανήτης τα τελευταία χρόνια και όσο περνάει ο καιρός αυτό φαίνεται να διογκώνεται. Το κίνητρο για την εκπόνηση της παρούσας διδακτορικής διατριβής στηρίζεται στην ανάγκη για απόλυτη κατανόηση των φαινομένων που λαμβάνουν χώρα κατά τη χρήση των ΑΠΕ σε διάφορα συστήματα για την παραγωγή ηλεκτρικής ενέργειας. Επιπλέον, μέσα από αυτή την έρευνα θα φανεί πως οι καιρικές συνθήκες επηρεάζουν τη συμπεριφορά ενός υβριδικού συστήματος και σε ποιό ποσοστό. Ακόμα περιμένουμε να γίνει φανερό το πόσο σημαντική είναι η σωστή επιλογή των τεχνολογιών σύμφωνα με τις ηλεκτρικές ανάγκες που πρέπει να καλυφθούν από ένα εγκατεστημένο σύστημα. Στη συνέχεια της παρούσας εργασίας μελετήθηκε κάτω από ποιες συνθήκες ένα αυτόνομο υβριδικό σύστημα μπορεί να είναι εφικτό καθώς και πόσο ακριβή αποτελέσματα μπορούν αν δώσουν τα θεωρητικά μαθηματικά μοντέλα επάνω στην πρόβλεψη της λειτουργίας ενός συστήματος. Τέλος, παρουσιάστηκε πως μπορεί να ενισχυθεί ο οικολογικός χαρακτήρας ενός συστήματος ενώ την ίδια στιγμή αποκαλύφθηκε η κύρια αδυναμία του κατά τη λειτουργία καθώς και πως αυτή μπορεί να λυθεί με τη χρήση καινοτόμων συσκευών για την αποθήκευση ενέργειας. Μέσω της παρούσας διδακτορικής διατριβής αποδείχθηκε πως ένα υβριδικό σύστημα υποστηριζόμενο από ΑΠΕ μπορεί να μετατραπεί σε εντελώς αυτόνομο με ενισχυμένο τον οικολογικό του χαρακτήρα και με την οικονομική και ενεργειακή βιωσιμότητά του να κυμαίνεται σε υψηλά επίπεδα. Το παραπάνω συμπέρασμα προέκυψε μέσω θεωρητικών αλλά και πειραματικών προσομοιώσεων διάφορων υβριδικών μονάδων. Αυτό αποτελεί ίσως το πιο ενθαρρυντικό στοιχείο για πλήρη αξιοποίηση των ΑΠΕ προκειμένου να καλυφθούν οι παγκόσμιες ενεργειακές ανάγκες με τρόπους εντελώς φιλικούς προς το περιβάλλον στο άμεσο μέλλον.

Renewable energy sources (RES)

Hybrid systems

Theoretical simulation

Experimental simulation

Energy buffering

Theoretical simulation tools

Flywheels

621.042

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