Search

Your search keyword '"Rinne, Erkka"' showing total 31 results
Start Over Author "Rinne, Erkka"
31 results on '"Rinne, Erkka"'

1. Comparison of shortwave radiation dynamics between boreal forest and open peatland pairs in southern and northern Finland.

Author

Peräkylä, Otso, Rinne, Erkka, Ezhova, Ekaterina, Lintunen, Anna, Lohila, Annalea, Aalto, Juho, Aurela, Mika, Kolari, Pasi, and Kulmala, Markku

Subjects
LEAF area index, SOLAR radiation, FOREST thinning, SNOW accumulation, ALBEDO
Abstract

Snow cover plays a key role in determining the albedo and thus the shortwave radiation balance of a surface. The effect of snow on albedo is modulated by land use: tree canopies break the uniform snow layer and lower the albedo as compared to an open ground. This results in a higher fraction of shortwave radiation being absorbed in forests. At seasonally snow-covered high latitudes, this lowering of the albedo has been suggested to offset some or all of the climate cooling effect of the carbon stored by forests. We used long-term in situ measurements to study the albedo and shortwave radiation balance of two pairs of sites, each consisting of an open peatland and a forest. One pair is located in northern and one in southern Finland in the boreal zone. We found that both forest sites had a low, constant albedo during the snow-free period. In contrast, both peatland sites had a higher snow-free albedo, with a clear seasonal cycle. The albedo was found to depend on the diffuse fraction of the incoming radiation: during the snow-covered period, higher diffuse fraction was associated with lower albedo, while during the snow-free period it was associated with higher albedo. The thinning of the southern forest site, resulting in a significant reduction of the leaf area index, increased the albedo especially in the snow-covered period. During the snow-covered period, the peatland sites again had higher albedo than the forest sites. The transition between the high and low albedo upon snow accumulation and especially snowmelt was more abrupt at the peatland sites. In the northern pair, the forest site absorbed on average 0.47 GJ m−2 more (around 23 % more) energy from net shortwave radiation than the peatland site annually, whereas in the southern pair, the forest site absorbed on average 0.37 GJ m−2 more (around 14 % more) than the peatland site. The difference in the annual absorbed energy between the peatland site and the forest site was greater in the northern pair due to longer snow-cover duration. This was partially offset by the greater difference in snow-free albedos and higher solar radiation at the southern site pair. The annual difference in the absorbed shortwave radiation between the forest site and the peatland site varied considerably between the years (from 0.37 to 0.61 GJ m−2 for the northern pair and from 0.20 to 0.53 GJ m−2 for the southern pair). The annual variation was mainly controlled by the snow-cover duration in the spring at the peatland sites. These findings have implications for the future climate, as snow cover continues to evolve under global warming. [ABSTRACT FROM AUTHOR]

Published
2025
Full Text
View/download PDF

3. Comparison of shortwave radiation dynamics between boreal forest and open peatland pairs in southern and northern Finland.

Author

Peräkylä, Otso, Rinne, Erkka, Ezhova, Ekaterina, Lintunen, Anna, Lohila, Annalea, Aalto, Juho, Aurela, Mika, Kolari, Pasi, and Kulmala, Markku

Subjects
TAIGAS, SNOWMELT, SNOW accumulation, TUNDRAS, RADIATION, ALBEDO, SNOW cover
Abstract

Snow cover plays a key role in determining the albedo, and thus the shortwave radiation balance, of a surface. The effect of snow on albedo is modulated by land use: tree canopies break the uniform snow layer, and lower the albedo, as compared to an open ground. This results in a higher fraction of shortwave radiation being absorbed in forests. At seasonally snow-covered high latitudes, this lowering of the albedo has been suggested to offset some or all of the climate cooling effect of the carbon stored by forests. We used long-term in situ measurements to study the albedo and shortwave radiation balance of two pairs of sites, each consisting of an open peatland and a forest. One pair is located in northern and one in southern Finland in the boreal zone. We found that both forest sites had a low, constant albedo during the snow-free period. In contrast, both peatland sites had a higher snow-free albedo, with a clear seasonal cycle. This seasonal cycle was presumably caused by changing near-infrared albedo, as the albedo for photosynthetically active radiation was considerably more constant over the season. During the snow-covered period, the peatland sites again had higher albedo than the forest sites. The transition between the high and low albedo upon snow accumulation and especially snowmelt was more abrupt at the peatland sites. The annual difference in absorbed shortwave radiation between the peatland and the forest site was greater in the northern site pair, due to longer snow cover duration. This was partially offset by the greater difference in snow-free albedos at the southern site pair. Annual variation in the differences in absorbed shortwave radiation between forest and peatland sites was mainly controlled by the snow melt date at the peatland sites. These findings have implications for the future climate, as snow cover continues to evolve under global warming. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

6. Spine Toolbox : A flexible open-source workflow management system with scenario and data management

Author

Kiviluoma, Juha, Pallonetto, Fabiano, Marin, Manuel, Savolainen, Pekka T., Soininen, Antti, Vennström, Per, Rinne, Erkka, Huang, Jiangyi, Kouveliotis Lysikatos, Iasonas, Ihlemann, Maren, Delarue, Erik, O’Dwyer, Ciara, O’Donnel, Terence, Amelin, Mikael, Söder, Lennart, Dillon, Joseph, Kiviluoma, Juha, Pallonetto, Fabiano, Marin, Manuel, Savolainen, Pekka T., Soininen, Antti, Vennström, Per, Rinne, Erkka, Huang, Jiangyi, Kouveliotis Lysikatos, Iasonas, Ihlemann, Maren, Delarue, Erik, O’Dwyer, Ciara, O’Donnel, Terence, Amelin, Mikael, Söder, Lennart, and Dillon, Joseph

Abstract

The Spine Toolbox is open-source software for defining, managing, simulating and optimising energy system models. It gives the user the ability to collect, create, organise, and validate model input data, execute a model with selected data and finally archive and visualise results/output data. Spine Toolbox has been designed and developed to support the creation and execution of multivector energy integration models. It conveniently facilitates the linking of models with different scopes, or spatio-temporal resolutions, through the user interface. The models can be organised as a direct acyclic graph and efficiently executed through the embedded workflow management engine. The software helps users to import and manage data, define models and scenarios and orchestrate projects. It supports a self-contained and shareable entity-relationship data structure for storing model parameter values and the associated data. The software is developed using the latest Python environment and supports the execution of plugins. It is shipped in an installation package as a desktop application for different operating systems., QC 20220406

Published
2022
Full Text
View/download PDF

7. D4.8 - Open-access tool of linked electricity market models

Author

Rinne, Erkka, Schimeczek, Christoph, Algarvio, Hugo, Santos, Gabriel, Cvetkovic, Milos, Sanchez Jimenez, Ingrid, Vries, Laurens de, Hernandez Serna, Ricardo, Morales, german, and Sijm, Jos

Subjects
workflow, electicity market models, model coupling, agent-based modeling, SPINE toolbox, open-access
Published
2021

8. Open-access tool of linked electricity market models: Deliverable D4.8

Author

Rinne, Erkka, Schimeczek, Christoph, Algarvio, Hugo, Santos, Gabriel, Cvetkovic, Milos, Jimenez, Ingrid Sanchez, Vries, Laurens de, Serna, Ricardo Hernandez, Morales-España, Germán, Sijm, Jos, and Estanqueiro, Ana

Subjects
Electricity markets, Agent-based modeling, Open access markets
Abstract

Project TradeRES - New Markets Design & Models for 100% Renewable Power Systems: https://traderes.eu/about/ ABSTRACT: For a holistic understanding and simulation of the energy markets, many different aspects need to modelled properly. Often no single modelling tool offers the whole picture, but a combination of methods needs to be used. A model linkage platform has been chosen previously and this deliverable describes the integration of the modelling tools used in TradeRES to the linking application, Spine Toolbox. Spine Toolbox was used to build data processing and execution workflows around the energy system modelling tools Backbone, AMIRIS, EMLab, COMPETES, RESTrade and MASCEM. The aim is to integrate selected tools together for answering the research questions in the TradeRES project. The integrations of individual tools and some combinations are described in this document. Mostly, the work is still in progress. Also, a common database to serve the case studies has been created, but populating the database with scenario data is still in progress. A common data model to serve all the modelling tools has been created and the database is implemented using Spine Toolbox. N/A

Published
2021

10. Spine Toolbox: A flexible open-source workflow management system with scenario and data management

Author

Kiviluoma, Juha, primary, Pallonetto, Fabiano, additional, Marin, Manuel, additional, Savolainen, Pekka T., additional, Soininen, Antti, additional, Vennström, Per, additional, Rinne, Erkka, additional, Huang, Jiangyi, additional, Kouveliotis-Lysikatos, Iasonas, additional, Ihlemann, Maren, additional, Delarue, Erik, additional, O’Dwyer, Ciara, additional, O’Donnel, Terence, additional, Amelin, Mikael, additional, Söder, Lennart, additional, and Dillon, Joseph, additional

Published
2022
Full Text
View/download PDF

11. Spine Deliverable 2.1 Software Design Document

Author

Savolainen, Pekka T., Kiviluoma, Juha, Rinne, Erkka, Soininen, Antti, Dillon, Joseph, and Marin, Manuel

Subjects
Horizon 2020, GeneralLiterature_MISCELLANEOUS
Abstract

Spine Toolbox is an application that provides means to define, manage, and execute energy system models. It gives the user the ability to collect, create, organize, and validate model input data, execute a model with selected data and finally archive and visualize the results or output data. Spine Toolbox is designed to support the creation and execution of scenarios in optimization and simulation. In the Spine project, the main use case has been SpineOpt, which is a highly adaptable model generator for multi-energy systems. In addition, Spine Toolbox supports a wide variety of other models and tools if they follow the conventions of Spine Toolbox or there is an interpreter between the application and the external tool. One of the conventions is the Spine data structure, which is an entity-relationship data model for a structured yet flexible storage of data. The interface to the data structure is an integral part of both Spine Toolbox and SpineOpt because it enables them to communicate using a common vocabulary. Spine Toolbox is implemented in Python and SpineOpt in Julia.This deliverable presents a high-level software design for Spine Toolbox and for the various tools it supports. It contains the application use cases, functional and non-functional requirements, system overview, chosen implementation language(s), dependencies, versioning, application validation requirements, testing and security requirements, and general development guidelines. The aforementioned have been collected in co-operation with Spine members and stakeholders, who have been using Spine Toolbox since its inception. The last chapter presents an overview of the Spine data structure. The first version of this deliverable was published in project M02 and this final version presents the updated design of the software. Spine is an open-source project. In the fall of 2018, Spine Toolbox source code and documentation was released to the public. Spine Toolbox as well as the whole Spine software suite is available in a web-based version control repository system called GitHub (https://github.com/Spine-project). In addition, the user guide and other documentation is available on https://readthedocs.org/. Spine Toolbox is licensed under the GNU Lesser General Public License (LGPL). Spine Toolbox documentation, user guide and all original graphics have been released with the Creative Commons BY-SA 4.0 license. We hope to attract a lively and active community around the Spine software suite that will continue development also after the project has ended.

Published
2021

12. Market model communication interfaces

Author

Couto, António, Schimeczek, Christoph, Rinne, Erkka, Lopes, Fernando, Santos, Gabriel, Algarvio, Hugo, Sanchez Jimenez, Ingrid, Vries, Laurens de, Cvetkovic, Milos, Hernandez, Ricardo, and Pinto, Tiago

Subjects
interfaces, communication, market model
Published
2020

14. Local flexibility markets:Smart Otaniemi D4.1

Author

Koreneff, Göran, Similä, Lassi, Forsström, Juha, Rinne, Erkka, Schöpper, Carina, Segerstam, Jan, Repo, Sirpa, and Kilkki, Olli

Abstract

This report is part of the results of Smart Otaniemi WP 4, Local flexibility market. Smart Otaniemi is a smart energy piloting area and ecosystem in Otaniemi, Espoo. This report includes a state-of-the-art analysis of local markets, especially in Germany and the UK, and of the system wide markets in Finland, in which demand response can almost conclusively participate, aggregated or not. The notion of local flexibility markets hits the first snag with the question of who will buy the local flexibility in Finland: analysis shows that it is not other end-users, not the seller per se, nor the local generator unless it is a clearly better solution than selling to the energy market. For example, although a small end-user does not participate in the spot market directly, she can use her flexibility via market price based contracts. The main answer is the DSO. The DSO’s demand for flexibility might have different reasons such as local ancillary service needs or fighting bottlenecks. However, in general, flexibility should be available for multiple uses in order to enable value stacking. Local energy markets could be practical for reasons other than the utilization of flexibility for the management of the local network. Local markets could enable more specialised or granular trading, especially if trading is not possible on existing markets for the interested stakeholders. In addition, the local markets could act as an aggregation platform for existing markets. The more markets and interested parties, including independent aggregators, are involved, the more important and complicated balance settlement will become. One option of simplifying things that this research came up with is to elevate all end-users to the status of balance responsible. To better understand the balance implications for different parties under various conditions, a balance model was created. The report presents a general framework for flexibility markets (Smart Otaniemi logic) consisting of considerations for balance responsibility and product design. The framework could be implemented in Otaniemi and beyond.

Published
2020

16. Backbone: An adaptable energy systems modelling framework

Author

Helistö, Niina, Kiviluoma, Juha, Ikäheimo, Jussi, Rasku, Topi, Rinne, Erkka, O'Dwyer, Ciara, Li, Ran, and Flynn, Damian

Subjects
investment planning, power systems, stochastic programming, open source, modelling tools, SDG 7 - Affordable and Clean Energy, energy systems, modelling framework, unit commitment, variable renewable energy
Abstract

Backbone represents a highly adaptable energy systems modelling framework, which can be utilised to create models for studying the design and operation of energy systems, both from investment planning and scheduling perspectives. It includes a wide range of features and constraints, such as stochastic parameters, multiple reserve products, energy storage units, controlled and uncontrolled energy transfers, and, most significantly, multiple energy sectors. The formulation is based on mixed-integer programming and takes into account unit commitment decisions for power plants and other energy conversion facilities. Both high-level large-scale systems and fully detailed smaller-scale systems can be appropriately modelled. The framework has been implemented as the open-source Backbone modelling tool using General Algebraic Modeling System (GAMS). An application of the framework is demonstrated using a power system example, and Backbone is shown to produce results comparable to a commercial tool. However, the adaptability of Backbone further enables the creation and solution of energy systems models relatively easily for many different purposes and thus it improves on the available methodologies.

Published
2019
Full Text
View/download PDF

19. Hydropower Flexibility for Power Systems with Variable Renewable Energy Sources

Author

Huertas‐Hernando, Daniel, primary, Farahmand, Hossein, additional, Holttinen, Hannele, additional, Kiviluoma, Juha, additional, Rinne, Erkka, additional, Söder, Lennart, additional, Milligan, Michael, additional, Ibanez, Eduardo, additional, Martinez, Sergio M., additional, Gómez‐Lázaro, Emilio, additional, Estanqueiro, Ana, additional, Rodrigues, Luis, additional, Carr, Luis, additional, Roon, Serafin, additional, Orths, Antje, additional, Eriksen, Peter B., additional, Forcione, Alain, additional, and Menemenlis, Nickie, additional

Published
2019
Full Text
View/download PDF

20. Hydropower Flexibility for Power Systems with Variable Renewable Energy Sources: An IEA Task 25 Collaboration

Author

Huertas-Hernando, Daniel, Farahmand, Hossein, Holttinen, Hannele, Kiviluoma, Juha, Rinne, Erkka, Söder, Lennart, Milligan, Michael, Ibanez, Eduardo, Martinez, Sergio M., Gómez-Lázaro, Emilio, Estanqueiro, Ana, Rodrigues, Luis, Carr, Luis, van Roon, Serafin, Orths, Antje, Eriksen, Peter B., Forcione, Alain, Menemenlis, Nickie, Huertas-Hernando, Daniel, Farahmand, Hossein, Holttinen, Hannele, Kiviluoma, Juha, Rinne, Erkka, Söder, Lennart, Milligan, Michael, Ibanez, Eduardo, Martinez, Sergio M., Gómez-Lázaro, Emilio, Estanqueiro, Ana, Rodrigues, Luis, Carr, Luis, van Roon, Serafin, Orths, Antje, Eriksen, Peter B., Forcione, Alain, and Menemenlis, Nickie

Abstract

In order to effectively utilize hydro production flexibility, a sufficient amount of transmission capacity has to be available between the hydro-dominated part of the system and the part that requires operational flexibility. This chapter starts with a rough categorization of “base” hydropower flexibility, investigating the types of hydropower plants installed in power systems today. The “effective” hydropower flexibility available to support the integration of variable generation is a far more complex and case-specific aspect. It is discussed through national experiences. The chapter presents potential developments that would increase the participation of hydropower and discuss the ensuing challenges. Modeling a flow-based hydro system is a complex exercise, as is modeling the power system. Especially important is the correct assessment of hydropower flexibility to support power systems with a large share of variable generation (VG) and its value for storage. With increasing uncertainty and variability, a stochastic scheduling approach should yield lower costs., QC 20240314Part of ISBN 9781119508311Part of ISBN 9781119508281

Published
2019
Full Text
View/download PDF

23. Neo-Carbon Energy - final report

Author

Vainikka, Pasi, Breyer, Christian, Heinonen, Sirkka, Jero Ahola, Holttinen, Hannele, Honkapuro, Samuli, Hyppänen, Timo, Koljonen, Tiina, Kosonen, Antti, Kärki, Janne, Laaksonen, Petteri, Partanen, Jarmo, Savolainen, Jouni, Simell, Pekka, Tsupari, Eemeli, Tynjälä, Tero, Vakkilainen, Esa, Abdulganiyu, Ibrahim, Aghahosseini, Arman, Alakangas, Eija, Alhalabi, Tamer, Annala, Salla, Arminen, Heli, Arvonen, Anne, Azevedo, Miguel, Abdelrahman Azzuni, Bajamundi, Cyril, Raleigh, Nicolas Balcom, Maulidi Barasa, Björnberg, Amanda, Bogdanov, Dmitrii, Upeksha Caldera, Carvalho, Mariana, Child, Michael, Cordeiro, Jose, Elfving, Irene, Elfving, Jere, Orozco, Francisco Javier Farfan, Fasihi, Mahdi, Forsström, Juha, Frilund, Christian, Ghorbani, Narges, Gore, Olga, Gulagi, Ashish, Haikola, Juha, Hannula, Ilkka, Heikkinen, Niko, Heiskanen, Katja, Helistö, Niina, Hilber, Paavo, Hiltunen, Henri, Hokkanen, Tuomo, Holopainen, Antti, Holviala, Niina, Horvath, Stephen, Huoman, Kimmo, Hurkainen, Markus, Hytönen, Eemeli, Ihonen, Jari, Ikäheimo, Jussi, Inayatullah, Sohail, Inkeri, Eero, John, Elena, Jokimies, Päivi, Juuti, Juha, Kaijaluoto, Sakari, Kaikko, Juha, Kaisalo, Noora, Kangas, Petteri, Kannari, Lotta, Karjalainen, Joni, Karjunen, Hannu, Karppinen, Juha, Kauppinen, Juho, Keiner, Dominik, Keränen, Janne T., Siavash Khalili, Musharof Khan, Kihlman, Johanna, Kilickaplan, Anil, Kiviluoma, Juha, Koiranen, Tuomas, Koponen, Joonas, Koponen, Kati, Koskela, Kari, Koskinen, Otto, Mari-Leena Koskinen-Soivi, Kotisaari, Mikko, Koukkari, Pertti, Kuitunen, Aino, Kukkonen, Jouko, Kuparinen, Katja, Kuusi, Osmo, Kälviäinen, Esa, Laari, Arto, Lang, Merja, Leena-Maija Lauren, Lehtilä, Antti, Lehtoaro, Juha, Lehtonen, Juha, Leinonen, Teemu, Lindfors, Heikki, Loisa, Marjo, Lonka, Lea, Luoma, Hannu, Luomanperä, Kaija, Makkonen, Mari, Mikkola, Henri, Mikkonen, Hannu I., Muhola, Mirja, Nieminen, Harri, Niinimäki, Lauri, Nisula, Sakari, Barbosa, Larissa De Souza Noel Simas, Nordling, Alexander, Nyholm, Riitta, Onarheim, Kristin, Ayobami Solomon Oyewo, Pajarre, Risto, Parkkinen, Marjukka, Pasonen, Riku, Patala, Samuli, Peker, Bülent Onur, Peltoniemi, Pasi, Pennanen, Jari, Juha-Pekka Pitkänen, Poluektov, Anton, Puro, Liisa, Pursiheimo, Esa, Putkonen, Matti, Puumalainen, Kaisu, Pyrhönen, Olli, Rantanen, Eetu, Reinikainen, Matti, Reponen, Jussi, Rimppi, Heli, Rinne, Erkka, Ruokonen, Jaana, Ruokoniemi, Harri, Ruotsalainen, Juho, Ruuskanen, Vesa, Ryynänen, Tapani, Saarimäki, Pekka, Sadovskaia, Kristina, Salminen, Hazel, Salovaara, Kaisa, Savolainen, Pekka T., Sihvonen, Teemu, Sillman, Jani, Similä, Lassi, Soukka, Risto, Steinmüller, Karlheinz, Suikki, Antti, Suomalainen, Marjut, Tanskanen, Vesa, Taylor, Amos, Tervonen, Antero, Tikka, Ville, Toivanen, Reeta, Toktarova, Alla, Tähtinen, Matti, Uski, Sanna, Uusitalo, Ville, Vanadzina, Evgenia, Vastamäki, Pertti, Weiss, Robert, Vespäläinen, Jessica, Vazquez, Francisco Vidal, Vähäkari, Noora, Väisänen, Sanni, Väkiparta, Toni, Väätänen, Jutta, and Zavialova, Sofia

Published
2017
Full Text
View/download PDF

25. Hydro power flexibility for power systems with variable renewable energy sources: an IEA Task 25 collaboration

Author

Huertas‐Hernando, Daniel, primary, Farahmand, Hossein, additional, Holttinen, Hannele, additional, Kiviluoma, Juha, additional, Rinne, Erkka, additional, Söder, Lennart, additional, Milligan, Michael, additional, Ibanez, Eduardo, additional, Martínez, Sergio Martín, additional, Gomez‐Lazaro, Emilio, additional, Estanqueiro, Ana, additional, Rodrigues, Luis, additional, Carr, Luis, additional, van Roon, Serafin, additional, Orths, Antje Gesa, additional, Eriksen, Peter Børre, additional, Forcione, Alain, additional, and Menemenlis, Nickie, additional

Published
2016
Full Text
View/download PDF

26. Modelling framework for power systems

Author

Kiviluoma, Juha, Rinne, Erkka, Helistö, Niina, and Azevedo, Miguel

Subjects
economic dispatch, power flow, smart resources, SDG 7 - Affordable and Clean Energy, unit commitment, wind power, smart grid, generation planning
Abstract

The report summarizes the models and modelling framework (Sceleton) partially developed at VTT for analysing power systems with high share of variable generation. The framework covers regional geographic scale and time domains including investments, unit commitment, dispatch and power flows. Currently three models are included in the Sceleton framework: Balmorel, WILMAR JMM, and PSS@E. The operation of the models can be interlinked. Input data is contained in a single database. Sceleton organizes running multiple scenarios as well as plotting and storing results from the models.

Published
2014

27. Comparison of flexibility options to improve the value of variable power generation.

Author

Kiviluoma, Juha, Rinne, Erkka, and Helistö, Niina

Subjects
*ELECTRIC power production, *ENERGY economics, *ELECTRIC power transmission, *WATER power, *LOAD management (Electric power), *ENERGY storage
Abstract

As the share of variable generation in power systems increases, there is increasing value in more flexible use and generation of electricity. The paper compares the economic value of several flexibility options in a large power system with a large amount of reservoir hydro power. Generation planning models are needed to consider the impact of flexibility options on other investments in a power system. However, generation planning models do not include all the relevant operational details. The approach in the paper combines a generation planning model with a unit commitment and dispatch model. The results demonstrate the value of coupling the heat and power sectors and the value of transmission. Low-cost electricity storage does not appear to be as decisive in the Northern European context with wind power as the main variable generation source. The paper also addresses methodological issues related to the inclusion of operational constraints in generation planning. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

28. Improving water values in a stochastic electricity market model

Author

Rinne, Erkka

Subjects
hydropower, optimisation, electricity market model, wind power, water value
Abstract

The optimal use of reservoir hydropower is a complex problem. To describe the marginal value of a reservoir connected to a hydropower plant the term water value is used. In an electricity system with both hydropower and thermal capacity, water value is equal to the absolute change of total production costs when there is one unit more water available. Water value is a function of time and reservoir filling level. The less water in the reservoirs, the more valuable it is. Annual water inflow is unequally spread over the year and therefore affects the available amount of water and the water values. Increasing the share of wind power in electricity generation causes integration costs in the system. These costs are due to e.g. increased need for regulation. Reservoir hydropower is efficient in balancing the system with wind, but the use of reservoirs has to be re-optimised. Wilmar Joint Market Model (JMM) is a stochastic electricity market model created for the study of the effects of large scale wind integration. In this study a new method is presented to calculate water values for the JMM using VTT’s Markkinahintamalli (MH model). MH model is a tool for predicting electricity production costs in the Nordic countries. Wilmar Long Term Model, which is the original water value component of the JMM, and a method following historical reservoir levels were used as a comparison. The advantage of the MH model is the fast optimisation of water reservoirs using stochastic dynamic programming. It is also possible to calibrate the interplay with the JMM, unlike with the other two methods. Water values are calculated from the total cost function of the MH model. Water value is the derivative of the total cost function with respect to reservoir level. JMM was used to simulate electricity production in the Nordic countries during the year 2001. Three methods to calculate water values were compared. The most important results are marginal production costs, water reservoir levels and electricity production by generation type. These were compared with the historical data. The results with the new method are promising. The simulated reservoir levels throughout the year are very close to the historical values. Production shares are not accurate with any of the methods, but the production time series appears realistic and stable with the new MH model method. Additional work will be needed to calibrate and enhance the JMM and the MH model. The most important areas of development are the modelling of different kinds of reservoirs within both the JMM and the MH model, the defining of realistic plant outages as well as the share of run-of-river power and the estimation of the variable costs of hydropower production in the MH model. The long-term variation of wind power generation should also be included in the MH model.

Published
2011

29. Hydro power flexibility for power systems with variable renewable energy sources: an IEA Task 25 collaboration.

Author

Huertas-Hernando, Daniel, Farahmand, Hossein, Holttinen, Hannele, Kiviluoma, Juha, Rinne, Erkka, Söder, Lennart, Milligan, Michael, Ibanez, Eduardo, Martínez, Sergio Martín, Gomez-Lazaro, Emilio, Estanqueiro, Ana, Rodrigues, Luis, Carr, Luis, Roon, Serafin, Orths, Antje Gesa, Eriksen, Peter Børre, Forcione, Alain, and Menemenlis, Nickie

Subjects
RENEWABLE energy sources, ELECTRIC power production, HYDROLOGIC cycle
Abstract

Hydro power is one of the most flexible sources of electricity production. Power systems with considerable amounts of flexible hydro power potentially offer easier integration of variable generation, e.g., wind and solar. However, there exist operational constraints to ensure mid-/long-term security of supply while keeping river flows and reservoirs levels within permitted limits. In order to properly assess the effective available hydro power flexibility and its value for storage, a detailed assessment of hydro power is essential. Due to the inherent uncertainty of the weather-dependent hydrological cycle, regulation constraints on the hydro system, and uncertainty of internal load as well as variable generation (wind and solar), this assessment is complex. Hence, it requires proper modeling of all the underlying interactions between hydro power and the power system, with a large share of other variable renewables. A summary of existing experience of wind integration in hydro-dominated power systems clearly points to strict simulation methodologies. Recommendations include requirements for techno-economic models to correctly assess strategies for hydro power and pumped storage dispatch. These models are based not only on seasonal water inflow variations but also on variable generation, and all these are in time horizons from very short term up to multiple years, depending on the studied system. Another important recommendation is to include a geographically detailed description of hydro power systems, rivers' flows, and reservoirs as well as grid topology and congestion. WIREs Energy Environ 2017, 6:e220. doi: 10.1002/wene.220 For further resources related to this article, please visit the . [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

30. Spine Toolbox and Spine Model for Open Source Energy System Analysis.

Author

Kiviluoma, Juha, Amelin, Mikael, Delarue, Erik, Dillon, Jody, Ihlemann, Maren, Kaminski, Steffen, Lastusilta, Toni, Marin, Manuel, Olauson, Jon, Pallonetto, Fabiano, Poncelet, Kris, Rinne, Erkka, Savolainen, Pekka T., Söder, Lennart, and Vennström, Per

Subjects
OPEN source intelligence, ELECTRIC power system planning, ELECTRIC power production, ELECTRIC power system control, USER interfaces
Abstract

EU project Spine [1] is developing an open source toolbox and model for energy system modelling. The purpose is to offer a platform for data acquisition tools, data processing tools, and models of different temporal and/or geographic scope. The toolbox will help users to manage data, scenarios and modelling projects. It will allow connecting models of different scope through the toolbox interface. The poster presents the Spine Toolbox user interface, data structure and the interface for connecting external tools and models. It will also introduce the Spine Model, which is an adaptable energy systems optimization model integrated with the Spine Toolbox. [ABSTRACT FROM AUTHOR]

Published
2018

31. Cost Optimal Share of Wind Power, PV and Batteries.

Author

Kiviluoma, Juha, Azevedo, Miguel, Rinne, Erkka, and Helistö, Niina

Subjects
ELECTRIC power system planning, WIND power, PHOTOVOLTAIC power generation, STORAGE batteries, ENERGY storage
Abstract

A chronological multi-area generation planning model is used to investigate the influence of low-cost batteries on the cost-optimal share of wind power and photovoltaics (PV) under varying assumptions about their future investment costs. The analysis is performed in two different geographic locations that have a large difference in the solar resource. The results from around 400 scenario runs demonstrate to what extent lower investment costs mitigate the resource variability. In this regard, PV is more sensitive than wind power. Given the assumptions utilized, the model starts to invests in PV at much higher cost levels in Iberia (~1050 €/kW) than in Northern Europe (~400 €/kW). Furthermore, in Iberia batteries benefit PV strongly (already at 300 €/kWh) while in Northern Europe batteries are not as relevant, since PV has a strong seasonal variation that cannot be economically mitigated with batteries and the region already has high amounts of flexible reservoir hydro power. [ABSTRACT FROM AUTHOR]

Published
2015

Catalog

Books, media, physical & digital resources
See catalog results