Building Energy and Environmental Modelling (Core, 20 Credits) You will learn about powerful new and emerging tools for modelling building energy systems and control. You will develop skills for simulating energy systems of relevance to buildings as well as modelling air flow in and around buildings.

You will learn how to build dynamic energy, ventilation and comfort models for multizone buildings.

You will investigate building thermal response including comfort, energy, interzone air movement and future weather modelling of multizone informationKB7030 - Research Methods (Core, 20 Credits) Training in research methods provides researchers with an understanding of the 'dos' and 'don'ts' that are associated with employing particular approaches to the collection and analysis of data 16 May 2016 - Choice of method: A semi-comparative case study with mixed- By studying the variables of the technology and other resources of the firms, the University College. From the beginning of the writing process of the thesis, the PV technology was in focus. is on solar energy converted into electricity..

Awareness of research methodologies and methods will enable researchers to practice appropriate techniques and to implement methods accurately. The primary aim of the module is to inform and sensitise you to the choices that are available when planning to undertake a research project.

This includes making you aware of a selected range of qualitative and quantitative research methods that can be employed to collect and analyse primary and secondary data arising from studies using these methodological paradigms 0.2 The New Energy Conversion Technologies programme. 2. 0.3 Exergy. 4 In the case of the coal-fired steam boiler, a gas turbine cycle with an external heat..

Section 2: the project: aims, objectives - university of sussex

Of equal importance, the module will also introduce you to a range of academic skills that will support you during your programme of study in addition to the execution of your research informationKB7040 - Sustainable Development for Engineering Practitioners (Core, 20 Credits) This module will develop your understanding of the fundamentals of sustainable and ethical development for engineering practitioners, requiring your consideration of role and responsibility of the engineer within society. You will explore the fundamentals of sustainable development as they relate to decision making in engineering, for example consideration of; legislation, economics, energy, materials, environment and society.

During your study you will consider the challenges engineering activities present society and the future of our planet and seek solutions through the use of various techniques and tools such as the triple bottom line, stakeholder analysis, the circular economy, carbon footprint, material and energy supply chains and risk, the ethics of sustainable development and software tools for eco audit and life cycle assessment.

You will learn how to present a rational argument for sustainable solutions using both qualitative and quantitative data sources and tools using a wide range of published literature and also from your own informationKB7042 - Thermo-Mechanical Energy Conversion Systems (Core, 20 Credits) You will learn about technologies for the utilisation of renewable and sustainable energy sources for heat and power production using heat engines and other types of converters, specifically about the followings: •Solar, biomass, hydrogen and waste thermal energy resources •Principles of internal and external combustion engines for thermal conversion of Renewable Energy; Design and thermodynamics of Stirling Engines •Solar thermal energy: overview of low and high temperature solar thermal energy conversion Panacea, but the same year President Iimmy Carter signed a bill to turn massive thinking that has been exhibited in the past (as in the case of the MEEE), do not change. I began to study energy issues quite by chance. the late 19705 when I was asked to write a book for young people about the dramatic power failures .

Design and analysis of solar collectors for low temperature solar thermal energy conversion. High temperature solar power production technologies using concentrating mirrors •Heat and power plants operating with combustion of solid biomass•Technologies for production of biofuels.

Design of energy units operating on biofuels •Geo-thermal: conversion theory and technology, measurement techniques and design considerations•Hydrogen technology and fuel cells KB7043 - Multidisciplinary Design & Engineering Optimisation (Core, 20 Credits) You will learn about new design techniques and concepts in engineering and optimisation methods, specifically about the followings: •Design concepts: direct and inverse design, integrated design, multidisciplinary design, knowledge based design, design for X•Design process: conceptual/system-level/detail design, design decision support systems, multi-criteria decision analysis•Design for reliability: fault and failure, reliability analysis, fault tree analysis, reliability block diagram, failure mode and effect analysis, redundancy allocation, fail to safe design, fault tolerated design•Design under uncertainties: uncertainties in engineering design, deterministic and robust design, design sensitivity analysis, Monte Carlo and Taguchi methods•Optimisation problem formulation: constrained/unconstrained, linear/nonlinear, combinatorial, integer, single-/multi-objective, discrete/continuous/mixed, concave and convex problems•Multi-objective optimisation: Pareto frontier, aggregate objective function, goal programming •Search methods: gradient/hessian based, evolutionary techniquesMore informationKB7045 - Wind, Photovoltaic and Hybrid Renewable Energy Systems (Core, 20 Credits) You will learn about the theory and technology of renewable energy conversion systems, specifically about the followings: •Renewable resources, their characteristics and stochastic modelling•Wind turbines: components and performance measures, conceptual design, structural loads, blade and tower structural design considerations, operation and control•Aerodynamics of wind turbines: blade element momentum theory, blade aerodynamic design •Photovoltaic: conversion theory and technology, sizing and design considerations •Storage systems: power and cost modelling•Hybrid systems: power, cost and reliability/availability analyses and system architecture design for various configurations including wind, PV, battery, diesel and fuel cellMore informationKB7053 - Academic Language Skills for Mechanical and Construction Engineering (Optional, 0 Credits) Academic skills when studying away from your home institution can differ due to cultural and language differences in teaching and assessment practices.

This module is designed to support your transition in the use and practice of technical language and subject specific skills around assessments and teaching provision in your chosen subject area in the Department of Architecture and Built Environment When all forms of energy coming out of an energy conversion device are In the case of an electric bulb, the electrical energy is converted to light and heat..

The overall aim of this module is to develop your abilities to read and study effectively for academic purposes; to develop your skills in analysing and using source material in seminars and academic writing and to develop your use and application of language and communications skills to a higher level.

The topics you will cover on the module include:•Understanding assignment briefs and exam questions Energy and energy-using technologies from operating efficiently. The project employs a qualitative, case study methodology to achieve these What is the relative importance of each type of barrier and how does this vary between different .

•Developing academic writing skills, including citation, paraphrasing, and summarising.

Renewable and sustainable energy technologies with advanced

•Planning and structuring academic assignments (e.

New and advanced energy conversion technologies