Large-scale integration of renewable energies and impact on storage demand in a European renewable power system of 2050—Sensitivity study

Bußar, Christian; Stöcker, Philipp; Cai, Zhuang; Moraes, Luiz; Magnor, Dirk; Wiernes, Pablo Ezequiel; Bracht, Niklas van; Moser, Albert; Sauer, Dirk Uwe

doi:10.1016/j.est.2016.02.004

Cited by 139 publications

(58 citation statements)

References 11 publications

(20 reference statements)

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“…cold TES and solar PV technologies together. In general, by the increase of solar PV share higher short-term TES is required which is also consistent with findings of other researchers[80]. In other words, the higher the dependency of energy system on the solar PV, the higher the storage is needed to ensure the security of electricity supply of the system without intermittency and hence avoid possible penalties.For instance, in case of using 1500 kWh of TES a total annual savings of 8945 € could be achieved.…”

supporting

confidence: 90%

Optimized demand side management (DSM) of peak electricity demand by coupling low temperature thermal energy storage (TES) and solar PV

et al. 2018

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Cooling in the industry sector contributes significantly to the peak demand placed on an electrical utility grid. New electricity tariff structures include high charges for electricity consumption in peak hours which leads to elevated annual electricity costs for high-demanding consumers. Demand side management (DSM) is a promising solution to increase the energy efficiency among customers by reducing their electricity peak demand and consumption. In recent years, researchers have shown an increased interest in utilizing DSM techniques with thermal energy storage (TES) and solar PV technologies for peak demand reduction in industrial and commercial sectors. The main objective of the present study is to address the potential for applying optimization-based time-of-use DSM in the industry sector by using cold thermal energy storage and off-grid solar PV to decrease and shift peak electricity demands and to reduce the annual electricity consumption costs. The results show that when cold thermal energy storage and solar PV are coupled together higher annual electricity cost savings can be achieved compared to using these two technologies independently. Additionally, considerable reductions can be seen in electricity power demands in different tariff periods by coupling thermal energy storage with off-grid solar PV.

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supporting

confidence: 90%

Optimized demand side management (DSM) of peak electricity demand by coupling low temperature thermal energy storage (TES) and solar PV

et al. 2018

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“…Like the need for the energy capacity of the storage devices rises with increasing share of RES penetration, so does the need for storage power. Using a holistic model with a hierarchical management approach, Bussar et al recently found that a renewable power supply system for the EU-MENA region (Europe, Middle East and North Africa) would be most economic with a combination of storage devices having a total discharging power on the same order as the peak load, whereupon long-term storage was also found to need higher charging power than discharging power [19]. Furthermore, the discharge power of the long-term storage was found to be higher than the combined discharge power of both short-term and medium-term storage [19], which stresses the importance of long-term storage in future power systems based on (V)RES.…”

Section: Introductionmentioning

confidence: 99%

Optimal combination of energy storages for prospective power supply systems based on Renewable Energy Sources

Weitemeyer

Kleinhans

Siemer

et al. 2018

Journal of Energy Storage

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Prospective power supply systems based on Renewable Energy Sources require measures to balance power generation and load at all times. The utilisation of storage devices and backup power plants is widely suggested for this purpose, whereas the best combination is still to be found. In this work, we present a modelling approach to systematically study scenarios of future power supply systems with a high share of electricity originating from wind and solar resources. By considering backup as a subordinate source of electricity with energy-only costs, the approach is independent of the actual full-load hours of the backup power plants. Applying the approach to multi-year meteorological data for Germany, cost-optimised combinations of storage devices and backup power are identified. We find that even in scenarios with significant excess generation capacities there is a need for storage devices or backup power plants with discharging power on the same order as the average load to balance the system at all times. Furthermore, these capacities seem to be required in some years of the multi-year period only. Our results imply that the societal need of having electricity available at all times can likely be satisfied by installing over-capacities only, whereas a balance has to be found between installing additional backup or storage or generation capacities.

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“…Due to these simplifications, the results of the analysis are considered optimistic in terms of the power system's ability to dispatch energy, and will therefore overestimate the capacity to accommodate renewable energy production. On the other hand, PowerGAMA takes the physical power flow into account, which is a significant advantage over the power market simulators that only consider energy balance, such as the EMPS 3 model. An in-depth explanation of how PowerGAMA works is given in the PowerGAMA User…”

Section: Underlying Assumptions and Simplification In Powergamamentioning

confidence: 99%

“…Where equations (2)(3)(4)(5) are the constraints that delimit the variables. From the DC power flow equations [10], we have the power flow constraint (6), which describes the flow in the AC branches only.…”

Section: Mathematical Formulation Of Powergamamentioning

confidence: 99%

Validation study of an approximate 2014 European power‐flow model using PowerGAMA

Lie

Rye

Svendsen

et al. 2017

IET Generation, Transmission & Distribution

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This paper presents a validation study of an approximated model of the European power system in 2014. A lightweight and open source power-flow tool is used for this study. The tool and the model are publicly available and can be adapted to study future impact of large investments in the power system, specifically large-scale integration of renewable energy. The input data set is based on prior work, but it has been substantially updated for 2014. To maintain all aspects of the model open-source, only publicly available data was implemented. The modelling approach and simplifications are explained. Comparison of the simulation results with actual data on cross-border flows and energy mix for 2014 shows acceptable correlation. The model is able to capture main characteristics of the power system, such as reservoir handling, hydro pump pattern, and seasonal variation on cross-border flows.

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Large-scale integration of renewable energies and impact on storage demand in a European renewable power system of 2050—Sensitivity study

Cited by 139 publications

References 11 publications

Optimized demand side management (DSM) of peak electricity demand by coupling low temperature thermal energy storage (TES) and solar PV

Optimized demand side management (DSM) of peak electricity demand by coupling low temperature thermal energy storage (TES) and solar PV

Optimal combination of energy storages for prospective power supply systems based on Renewable Energy Sources

Validation study of an approximate 2014 European power‐flow model using PowerGAMA

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