Gestão sustentável da água em empreendimentos turísticos

O presente documento enquadra-se no âmbito do trabalho final do mestrado (TFM) do curso de Engenharia Civil, na área de especialização de Hidráulica, do Instituto Superior de Engenharia de Lisboa, sob a forma de um projeto na fase de estudo prévio com o título ―Gestão Sustentável da Água no empreendimento turístico Parque de Campismo da Ilha do Pessegueiro situado em Porto Covo - Região de Turismo do Alentejo‖. Este trabalho é constituído essencialmente por 5 partes. Sendo a primeira uma breve introdução às questões a abordar, a segunda corresponde à discrição teórica do uso eficiente da água baseando-se no PNEUA (Programa nacional para o uso eficiente da água). Já a terceira parte é relativa ao atual sistema de utilização da água no Parque de campismo da ilha do pessegueiro (PCIP), sendo a quarta o estudo do desenvolvimento do projecto para a gestão eficiente da água no empreendimento e a quinta parte o estudo de viabilidade económica e financeira a implementar no projecto. Para além da implementação de medidas de poupança são também objetivos principais deste trabalho a reutilização da água através da recolha, o tratamento e armazenamento das águas residuais e aproveitamento das águas pluviais para posterior abastecimento do sistema de utilização em descargas sanitárias, lavagem de pavimentos e regas de espaços verdes. São, portanto, três os subsistemas de gestão eficiente da água que se pretende implementar. Dá-se importância ao estudo de viabilidade económica do projeto, cujo período de retorno do capital investido em capitais próprios e alheios é de seis anos. Este projeto pretende dar apoio técnico ao uso eficiente da água no PCIP, de forma a conseguir por um lado obter vantagens económicas e por outro proteger o ambiente. As vantagens económicas são interessantes para orientar os recursos financeiros para outros investimentos e as questões ambientais são a base de uma campanha, já em curso, para obtenção de certificação energética, em conjunto com outras práticas já em curso, nomeadamente a recolha seletiva de resíduos sólidos para recircular e aproveitamento de energia solar.

AI in power systems and energy markets

In a world increasingly conscientious about environmental effects, power and energy systems are undergoing huge transformations. Electric energy produced from power plants is transmitted and distributed to end users through a power grid. The power industry performs the engineering design, installation, operation, and maintenance tasks to provide a high-quality, secure energy supply while accounting for its systems’ abilities to withstand uncertain events, such as weather-related outages. Competitive, deregulated electricity markets and new renewable energy sources, however, have further complicated this already complex infrastructure.Sustainable development has also been a challenge for power systems. Recently, there has been a signifi cant increase in the installation of distributed generations, mainly based on renewable resources such as wind and solar. Integrating these new generation systems leads to more complexity. Indeed, the number of generation sources greatly increases as the grid embraces numerous smaller and distributed resources. In addition, the inherent uncertainties of wind and solar energy lead to technical challenges such as forecasting, scheduling, operation, control, and risk management. In this special issue introductory article, we analyze the key areas in this field that can benefi t most from AI and intelligent systems now and in the future.We also identify new opportunities for cross-fertilization between power systems and energy markets and intelligent systems researchers.

Avaliação da rentabilidade económica dos sistemas de microgeração fotovoltaica em Portugal (1990-2010)

Dissertação para a obtenção do grau de Mestre em Engenharia Electrotécnica - ramo de Energia

Distributed Model Predictive Control for Housing with Hourly Auction of Available Energy

This paper presents a distributed model predictive control (DMPC) for indoor thermal comfort that simultaneously optimizes the consumption of a limited shared energy resource. The control objective of each subsystem is to minimize the heating/cooling energy cost while maintaining the indoor temperature and used power inside bounds. In a distributed coordinated environment, the control uses multiple dynamically decoupled agents (one for each subsystem/house) aiming to achieve satisfaction of coupling constraints. According to the hourly power demand profile, each house assigns a priority level that indicates how much is willing to bid in auction for consume the limited clean resource. This procedure allows the bidding value vary hourly and consequently, the agents order to access to the clean energy also varies. Despite of power constraints, all houses have also thermal comfort constraints that must be fulfilled. The system is simulated with several houses in a distributed environment.

A Voltage Limiter Circuit for Indoor Light Energy Harvesting Applications

A voltage limiter circuit for indoor light energy harvesting applications is presented. This circuit is a part of a bigger system, whose function is to harvest indoor light energy, process it and store it, so that it can be used at a later time. This processing consists on maximum power point tracking (MPPT) and stepping-up, of the voltage from the photovoltaic (PV) harvester cell. The circuit here described, ensures that even under strong illumination, the generated voltage will not exceed the limit allowed by the technology, avoiding the degradation, or destruction, of the integrated die. A prototype of the limiter circuit was designed in a 130 nm CMOS technology. The layout of the circuit has a total area of 23414 mu m(2). Simulation results, using Spectre, are presented.

Recuperação do isopentano da gasolina leve

Mestrado em Engenharia Química

Start-up circuit for low-power indoor light energy harvesting applications

A start-up circuit, used in a micro-power indoor light energy harvesting system, is described. This start-up circuit achieves two goals: first, to produce a reset signal, power-on-reset (POR), for the energy harvesting system, and secondly, to temporarily shunt the output of the photovoltaic (PV) cells, to the output node of the system, which is connected to a capacitor. This capacitor is charged to a suitable value, so that a voltage step-up converter starts operating, thus increasing the output voltage to a larger value than the one provided by the PV cells. A prototype of the circuit was manufactured in a 130 nm CMOS technology, occupying an area of only 0.019 mm(2). Experimental results demonstrate the correct operation of the circuit, being able to correctly start-up the system, even when having an input as low as 390 mV using, in this case, an estimated energy of only 5.3 pJ to produce the start-up.