290 research outputs found
Comparison of Medium-size Concentrating Solar Power Plants based on Parabolic Trough and Linear Fresnel Collectors
Abstract This paper compares the performance of medium-size Concentrating Solar Power (CSP) plants based on an Organic Rankine Cycle (ORC) power generation unit integrated with parabolic trough and linear Fresnel collectors. The CSP plants studied herein use thermal oil as heat transfer fluid and as storage medium in a two-tank direct thermal storage system. The performance of the CSP plants were evaluated on the basis of a 1 MW ORC unit with a conversion efficiency of about 24% and by considering different values of solar multiple and thermal storage capacity. The comparative performance analysis of the two CSP solutions was carried out with reference to the direct solar energy availability of Cagliari, Italy (1720 kWh/m2y) on a yearly basis by means of specifically developed simulation models. The results of the performance assessment demonstrate that CSP plants based on linear Fresnel collectors lead to higher values of electrical energy production per unit area of occupied land. The highest specific energy production of CSP plants based on linear Fresnel collectors is about 55-60 kWh/y per m2 of occupied land and it is achieved with solar multiples in the 1.74-2.5 range and storage capacities in the range of 4-12 hours. The highest specific production of the solutions based on parabolic trough collectors is about 45-50 kWh/y per m2 of occupied land and is achieved with lower solar multiples (around 1.5-2.3). Owing to their better optical efficiency, the use of parabolic troughs gives better values of energy production per unit area of solar collector (about 180-190 kWh/m2 vs. 130-140 kWh/m2)
Modeling and simulation of an isolated hybrid micro-grid with hydrogen production and storage
Abstract This work relates the study of system performance in operational conditions for an isolated micro-grid powered by a photovoltaic system and a wind turbine. The electricity produced and not used by the user will be accumulated in two different storage systems: a battery bank and a hydrogen storage system composed of two PEM electrolyzers, four pressurized tanks and a PEM fuel cell. One of the main problems to be solved in the development of isolated micro-grids is the management of the various devices and energy flows to optimize their functioning, in particular in relation to the load profile and power produced by renewable energy systems depending on weather conditions. For this reason, through the development and implementation of a specific simulation program, three different energy management systems were studied to evaluate the best strategy for effectively satisfying user requirements and optimizing overall system efficiency
Use of weather forecast for increasing the self-consumption rate of home solar systems: An Italian case study
With the aim of increasing the self-consumption rate of grid-connected Photovoltaic (PV) home systems, two main options can be implemented: the inclusion of an energy storage system, in particular a battery bank, and the adoption of a Demand Side Management (DSM) strategy. However, both the reshaping of the load consumption curve with the displacement of deferrable loads and the optimal management of the battery bank require estimation of the daily PV generation profile. The assessment of the on-site energy production can be carried out based on weather forecast data. However, the latter are characterized by uncertainty, which may affect the achievable self-consumption rate. This work investigates the influence of weather forecast errors on the performance of home PV systems equipped with a battery bank and characterized by a certain share of deferrable loads. Two different weather forecast services are considered, referring to the annual meteorological conditions occurring in Rome, and energy consumption data for 150 different households are analysed. The self-consumption rate is maximized by solving a suitable optimization problem, while different combinations of relative battery capacity, PV-to-load ratio and share of deferrable loads are considered. Two different approachesâ\u80\u94deterministic and stochasticâ\u80\u94are adopted and compared with an ideal approach where the PV generation profile is perfectly forecasted. The results show that the adoption of the deterministic approach leads to a reduction in the achievable self-consumption rate in the range of 0.5â\u80\u934.5% compared to the ideal approach. The adoption of a stochastic approach further reduces the deviations from the ideal case, especially in the case of consumption profiles with a high share of deferrable loads. Finally, a preliminary economic analysis proves that the use of a battery bank is not yet a cost-effective solution and a price reduction of the current battery prices is therefore required
A hydrogen-fuelled compressed air energy storage system for flexibility reinforcement and variable renewable energy integration in grids with high generation curtailment
Globally, the increasing share of renewables, prominently driven by intermittent sources such as solar and wind power, poses significant challenges to the reliability of current electrical infrastructures, leading to the adoption of extreme measures such as generation curtailment to preserve grid security. Within this framework, it is essential to develop energy storage systems that contribute to reinforce the flexibility and security of power grids while simultaneously reducing the share of generation curtailment. Therefore, this study investigates the performance of an integrated photovoltaic-hydrogen fuelled-compressed air energy storage system, whose configuration is specifically conceived to enable the connection of additional intermittent sources in already saturated grids. The yearly and seasonal performance of the integrated energy storage system, specifically designed to supply flexibility services, are evaluated for a scenario represented by a real grid with high-variable renewables penetration and frequent dispatchability issues. Results show that the integrated system, with performance-optimized components and a new energy management strategy, minimizes photovoltaic energy curtailment, otherwise around 50%, to as low as 4% per year, achieving system efficiencies of up to 62%, and reinforces the grid by supplying inertial power for up to 20% of nighttime hours. In conclusion, the integrated plant, operating with zero emissions, on-site hydrogen production, and optimized for non-dispatchable photovoltaic energy utilization, proves to be effective in integrating new variable renewable sources and reinforcing saturated grids, particularly during spring and summer
Social impact assessment of wind power generation. An innovative method for decision making processes
This paper explores the social impact for population in the energy sector combining
LCA and SIA (social impact assessment). As case study, a new 66 MW wind power plant under
development in the countryside of Southern Sardinia has been considered. The innovative
method, based on the analysis of the context, aims to empirically analyze some selected
sustainability indicators. The proposed method starts from a detailed analysis of the wind power
project, with particular reference to the plant site characteristics, technical features of the wind
farm, opinions of the stakeholders, environmental and social impacts and expected economic
benefits. The acquired data are validated with a Severity statistical method that identifies the
KPIs. The indicators are classified into general categories of damage Human life, Safety
guarantee, Social resources, Public participation and analyzed through a combined SIA-LCA
method to identify indicators damage weights.
This work shows the importance of putting together indicators already explored in the
environmental field such as Human health, Ecosystem quality, Resource, Climate Change and
as social indicators Renewable Energy with Noise, Visual Impact, Shadow Flichers, the
perceptions of the local community
Performance Analysis of a Diabatic Compressed Air Energy Storage System Fueled with Green Hydrogen
The integration of an increasing share of Renewable Energy Sources (RES) requires the availability of suitable energy storage systems to improve the grid flexibility and Compressed Air Energy Storage (CAES) systems could be a promising option. In this study, a CO2-free Diabatic CAES system is proposed and analyzed. The plant configuration is derived from a down-scaled version of the McIntosh Diabatic CAES plant, where the natural gas is replaced with green hydrogen, produced on site by a Proton Exchange Membrane electrolyzer powered by a photovoltaic power plant. In this study, the components of the hydrogen production system are sized to maximize the self-consumption share of PV energy generation and the effect of the design parameters on the H2-CAES plant performance are analyzed on a yearly basis. Moreover, a comparison between the use of natural gas and hydrogen in terms of energy consumption and CO2 emissions is discussed. The results show that the proposed hydrogen fueled CAES can effectively match the generation profile and the yearly production of the natural gas fueled plant by using all the PV energy production, while producing zero CO2 emissions
Life Cycle Assessment of an Integrated PV-ACAES System
The aim of this paper is to evaluate the overall life cycle environmental impact of an
adiabatic compressed air energy storage (ACAES) system, which is designed to achieve the best
match between the power production of a photovoltaic (PV) power plant and the power demand from
the final user. The electrical energy demand of a small town, with a maximum power load of about
10 MW, is considered a case study. The ACAES system is designed with a compressor-rated power of
about 10 MW and charging and discharging times of 10 and 24 h, respectively. Different sizes of the
PV plant, ranging from 20 to 40 MWp, and two different solutions for the compressed air storage,
an underground cavern, and a gas pipeline, are analyzed. The aim of this analysis is to compare
the impacts on human health, ecosystem quality, climate change, and resource consumption of the
PV power generation plant and the integrated PV-ACAES system with those of a reference scenario
in which the end user demand is met entirely by the grid. The best results in terms of a reduction
in environmental impact in comparison to the reference scenario are obtained for a small PV plant
(20 MW) without the ACAES section, with reductions of about 85–95% depending on the category of
impact. The integration of the ACAES system improves energy self-consumption but worsens the
environmental impact, especially for air storage in gas pipelines. The best configuration in terms of
environmental impact is based on a 30 MW PV plant integrated with an ACAES section using an
underground cavern for air storage and allows for improvements in the energy self-consumption
of between 38% and 61%, with a reduction in the environmental impact compared to the reference
scenario of about 80–91% depending on the impact categor
Le attivitĂ di ricerca del DIMECA nel settore della produzione di energia da biomasse
2008-11-25Aula Magna Facoltà di Ingegneria, CagliariLo stato dell’arte della ricerca scientifica nel settore della produzione di energia da biomass
Lo stato dell'arte della ricerca scientifica nel settore della produzione di energia da biomasse
2008-07-22Sala conferenze CIS, CagliariPresentazione del Laboratorio biocombustibili e biomass
I processi termochimici
2008-11-25Aula Magna Facoltà di Ingegneria, CagliariLo stato dell’arte della ricerca scientifica nel settore della produzione di energia da biomass
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