Risk-conscious design of off-grid solar energy houses

Hu, Huafen

16 November 2009

Zero energy houses and (near) zero energy buildings are among the most ambitious targets of society moving towards an energy efficient built environment. The "zero" energy consumption is most often judged on a yearly basis and should thus be interpreted as yearly net zero energy. The fully self sustainable, i.e. off-grid, home poses a major challenge due to the dynamic nature of building load profiles, ambient weather condition and occupant needs. In current practice, the off-grid status is accomplishable only by relying on backup generators or utilizing a large energy storage system. The research develops a risk based holistic system design method to guarantee a match between onsite sustainable energy generation and energy demand of systems and occupants. Energy self-sufficiency is the essential constraint that drives the design process. It starts with information collection of occupants' need in terms of life style, risk perception, and budget planning. These inputs are stated as probabilistic risk constraints that are applied during design evolution. Risk expressions are developed based on the relationships between power unavailability criteria and "damages" as perceived by occupants. A power reliability assessment algorithm is developed to aggregate the system underperformance causes and estimate all possible power availability outcomes of an off-grid house design. Based on these foundations, the design problem of an off-grid house is formulated as a stochastic programming problem with probabilistic constraints. The results show that inherent risks in weather patterns dominate the risk level of off-grid houses if current power unavailability criteria are used. It is concluded that a realistic and economic design of an off-grid house can only be achieved after an appropriate design weather file is developed for risk conscious design methods. The second stage of the research deals with the potential risk mitigation when an intelligent energy management system is installed. A stochastic model based predictive controller is implemented to manage energy allocation to sub individual functions in the off-grid house during operation. The controller determines in real time the priority of energy consuming activities and functions. The re-evaluation of the risk indices show that the proposed controller helps occupants to reduce damages related to power unavailability, and increase thermal comfort performance of the house. The research provides a risk oriented view on the energy self-sufficiency of off-grid solar houses. Uncertainty analysis is used to verify the match between onsite sustainable energy supply and demand under dynamic ambient conditions in a manner that reveals the risks induced by the fact that new technologies may not perform as well as expected. Furthermore, taking occupants' needs based on their risk perception as constraints in design evolution provides better guarantees for right sized system design.

Off-grid solar house

Power reliability

Uncertainty analysis

Model based control

Building simulation

Dwellings Energy conservation

Stochastic programming

Stochastic models

Renewable energy sources

Optimization of battery pack assembly of second life cells to reduce costs

Chowdry, Akash Prasad

January 2022

Batteries account for 50% of the overall cost of solar home systems (SHS). The battery packs degrade over time and when they reach 70% state of health (SOH), the whole SHS is discarded. In the predominantly rural off-grid context, battery replacements are expensive and impractical. The customers are often dozens of km away from any sales point. Furthermore, recycling schemes are often limited in the developing world, meaning that old batteries are sometimes discarded in unsafe ways. As the market grows, the environmental impact of this will only get larger. Solaris Offgrid, a premier name in the Solar Offgrid industry, is innovating two solutions designed to tackle this issue; a smart multi-battery packmanager and an easy to recycle battery pack design with cell by cell management. The current study is based on a lossless cell balancing design, where in the charge and discharge cycles of each cell in the string are monitored and to efficiently avoid overcharge and over-discharge. Implementing this strategy reduces the degradation of these batteries which extends the battery life of SHS. A sensitivity analysis is performed to analyze the environmental benefit gained by implementing lossless cell balancing. The thesis provides a literature study on the different battery terminologies, types of batteries used in SHS and, various cell-balancing techniques used today. This is followed by the design of a lossless cell balancing technique with minimal losses. / Batterierna står för 50 % av den totala kostnaden för solcellsanläggningar (SHS). Batteripaketen försämras med tiden och när de når 70 % av sitt hälsotillstånd kasseras hela solcellssystemet. På den övervägande landsbygden utanför elnätet är det dyrt och opraktiskt att byta ut batterierna. Kunderna befinner sig ofta tiotals kilometer från varje försäljningsställe. Dessutom är återvinningssystemen ofta begränsade i utvecklingsländerna, vilket innebär att gamla batterier ibland kasseras på ett osäkert sätt. I takt med att marknaden växer kommer miljöeffekterna av detta att bli allt större. Solaris Offgrid, som är ett ledande företag inom industrin för solcellsanläggningar, utvecklar två lösningar för att lösa detta problem: en smart batteripackförvaltare för flera batterier och en lätt återvinningsbar batteripackkonstruktion med cellvis hantering. Den aktuella studien bygger på en “förlustfri” cellbalanseringskonstruktion, där laddnings- och urladdningscyklerna för varje cell i strängen övervakas och effektivt undviker överladdning och överladdning. Genom att tillämpa denna strategi minskas degraderingen av dessa batterier, vilket förlänger batteritiden för SHS. En känslighetsanalys utförs för att analysera den miljöfördel som uppnås genom att införa förlustfri cellbalansering. Avhandlingen innehåller en litteraturstudie om olika batteriterminologier, typer av batterier som används i SHS och olika tekniker för cellbalansering som används idag. Detta följs av utformningen av en teknik för förlustfricellbalansering med minimala förluster.

Batteries

second life cells

active cell balancing

lossless cell balancing

off-grid solar

solar home systems

Batterier

second life cells

aktiv cellbalansering

förlustfri cellbalansering

solceller utanför nätet

solcellssystem för hemmabruk.

Engineering and Technology

Teknik och teknologier

Fotovoltaické dobíjecí regulátory v ostrovních systémech / Solar charge controllers for off-grid systems

KRČKA, Pavel

January 2013

This diploma thesis deals with photovoltaic rechargable regulators used in isolated, or off-grid photovoltaic systems. First, basic types of off-grid installations, including their functions and applications in practice are described. Then, possibilities of electric energy accumulation in photovoltaic systems are mentioned, considering actual, accesible technologies. Matters of electric energy accumulation in leaden accumulators are examined in detail. Main part of the diploma thesis is about electronic designs of photovoltaic, also called solar, rechargable regulators. These are the main connecting part between photovoltaic panels, accumulator, but also often connected charge, which is appliance. Individual electronic regulators concepts are described narrowly, then compared and evaluated in thesis´ conclusion.