Power Electronic Stages for a TFPMSM in Wave Power Applications

Falk Olson, Gustaf

January 2016

Direct drive wave energy conversion systems have been identified as a potentially major contributor to the world’s energy demands, forecasting shares of up to 25 % of the energy mix. Anders Hagnestål conducts research at the Royal Institute of Technology where a novel linear transverse flux permanent magnet generator is developed. This concept machine is particularly well-suited for the pertaining operating conditions in marine environments, producing large forces at low speeds with outstandingly low resistive losses. However, it exhibits severe magnetic saturation and draws unsymmetrical phase currents at nominal operation. In addition, it possesses a low power factor. All in all, this places stern requirements on the power electronic system and control algorithms. The aim of this thesis has been to design a functioning power conditioning system that connects the machine to the electric grid. For this purpose, a three-phase two-level voltage source converter is proposed to be back-to-back connected with two-level single-phase voltage source converters (active rectifiers) interfacing each and every machine phase. It is shown that the intermediate DC link can be maintained at a constant voltage with restricted ripple while feeding power at unity power factor to the grid by appropriately sizing the DC capacitor and adopting a feedback linearization control scheme. The phase currents can be controlled effectively by means of a cascaded gain-scheduled PID controller. By including a low-pass filter the iron losses in the machine may be suppressed even at lower switching frequencies. A constrained cost optimization indicates that the converter consequently can reach 99.1 % efficiency. Finally, with this thesis as a background, it is suggested that the thermal stresses on the selected semiconductor modules and the iron losses of the machine are evaluated to further improve the design. If higher efficiency of the active rectifiers is strived for, more complex converter topologies could be considered. / Direktdrivna vågenergiomvandlingssystem har utpekats som en potentiellt starkt bidragande resurs för att tillgodose världens efterfrågan på energi med andelar på uppemot 25 % av energimixen förutspådda. Anders Hagnestål bedriver forskning och utveckling av en ny typ av linjär permanentmagnetiserad transversalflödesmaskin vid Kungliga Tekniska Högskolan. Konceptmaskinen är särskilt väl lämpad för de rådande marina förhållandena genom att kunna producera stora krafter vid låga hastigheter med utomordentligt låga resistiva förluster. Maskinen går emellertid i kraftig magnetisk mättnad och drar asymmetriska strömmar vid nominell drift. Dessutom är effektfaktorn låg i jämförelse med standardmaskiner. Alltsomallt inför detta hårda krav på det effektelektroniska systemet och kontrollalgoritmerna. Målet med detta examensarbete har varit att designa ett funktionellt effektkonditioneringssystem som sammanfogar maskinen med det angränsande elektriska nätet. För att åstadkomma detta föreslås att en tvånivås-trefasomriktare kopplas rygg-mot-rygg till tvånivås-enfasomvandlare (aktiva likriktare) som i sin tur är kopplade till varje maskinfas. Med den här konfigurationen visas det att spänningen på den mellanliggande DC-länken kan hållas konstant med begränsat rippel, alltmedan effekt tillförs nätet vid effektfaktor ett genom att dimensionera DC-kondensatorn på rätt sätt och använda en kontrollag baserad på exakt linjärisering. Maskinens fasströmmar kan kontrolleras effektivt med hjälp av en kaskadkopplad PID-regulator med schemalagda förstärkningsfaktorer. Genom att inkludera ett lågpassfilter förväntas det att järnförlusterna i maskinen kan begränsas även vid lägre switchfrekvenser. Genom att lösa ett kostnadsoptimeringsproblem visas det att den resulterande aktiva likriktaren kan uppnå en verkningsgrad på 99.1 %. Slutligen, med det här examensarbetet som grund, föreslås det att den termiska stressen på de valda halvledarkomponentsmodulerna och järnförlusterna i maskinen utvärderas för att ytterligare förbättra designen. Om högre verkningsgrad eftersträvas hos de aktiva likriktarna kan mer komplicerade omvandlartopologier övervägas.

active rectifier

direct drive wave energy converter

feedback linearization

cascaded PID controller.

Engineering and Technology

Teknik och teknologier

Modelling and Advanced Control of Fully Coupled Wave Energy Converters Subject to Constraints: the Wave-to-wire Approach

Wang, Liguo

January 2017

Ocean wave energy is a promising renewable source to contribute to supplying the world’s energy demand. The Division of Electricity at Uppsala University is developing a technology to capture energy from ocean waves with a wave energy converter (WEC) consisting of a linear permanent magnet generator and a point absorber. The linear generator is placed on sea bed and is driven directly by the floating absorber. Since March 2006, multiple wave energy converters have been deployed on the Swedish west coast outside the town of Lysekil. The technology is verified by long-term operation during at sea and satisfactory reliability of the electricity generation. This thesis focuses on developing advanced control strategies for fully coupled wave energy converters subject to constraints. A nonlinear control strategy is studied in detail for a single WEC subject to constraints under regular and irregular waves. Besides, two coordinated control strategies are developed to investigate the performance of a wave energy farm subject to constraints. The performance of the WECs using these control strategies are investigated in case studies, and optimal PTO damping coefficients are found to maximize the output power. The results show that these control strategies can significantly improve the performance of the WECs, in terms of mean power, compared to a conventional control. Besides these control strategies, a wave-to-wire simulation platform is built to study the power generation control of the WEC subject to constraints.  The wave-to-wire simulation platform allows both nonlinear and linear control force. The results show that there is a good agreement between the desired value and the actual value after advanced control.

Ocean wave energy

marine energy converter

wave energy converter

wave energy farm

potential flow theory

linear permanent magnet generator

control strategy

wave-to-wire approach

physical constraints

power generation control.

Engineering and Technology

Teknik och teknologier

Ocean Wave Energy : Underwater Substation System for Wave Energy Converters

Rahm, Magnus

January 2010

This thesis deals with a system for operation of directly driven offshore wave energy converters. The work that has been carried out includes laboratory testing of a permanent magnet linear generator, wave energy converter mechanical design and offshore testing, and finally design, implementation, and offshore testing of an underwater collector substation. Long-term testing of a single point absorber, which was installed in March 2006, has been performed in real ocean waves in linear and in non-linear damping mode. The two different damping modes were realized by, first, a resistive load, and second, a rectifier with voltage smoothing capacitors and a resistive load in the DC-link. The loads are placed on land about 2 km east of the Lysekil wave energy research site, where the offshore experiments have been conducted. In the spring of 2009, another two wave energy converter prototypes were installed. Records of array operation were taken with two and three devices in the array. With two units, non-linear damping was used, and with three units, linear damping was employed. The point absorbers in the array are connected to the underwater substation, which is based on a 3 m3 pressure vessel standing on the seabed. In the substation, rectification of the frequency and amplitude modulated voltages from the linear generators is made. The DC voltage is smoothened by capacitors and inverted to 50 Hz electrical frequency, transformed and finally transmitted to the on-shore measuring station. Results show that the absorption is heavily dependent on the damping. It has also been shown that by increasing the damping, the standard deviation of electrical power can be reduced. The standard deviation of electrical power is reduced by array operation compared to single unit operation. Ongoing and future work include the construction and installation of a second underwater substation, which will connect the first substation and seven new WECs.

wave energy

wave power

wave energy converter

direct-drive

permanent magnet linear generator

point absorber

array

farm

park

offshore

marine

substation

electrical transmission system

Elektroteknik, elektronik och fotonik

Modélisation de fermes de systèmes houlomoteurs : effets d’interactions entre systèmes à l’échelle de la ferme et impact sur le climat de vagues à l'échelle régionale / Numerical modeling of arrays of wave energy converters : interaction effects between units at the scale of an array and impact on wave climatology at the regional scale

Charrayre, François

17 September 2015

Cette thèse porte sur le développement d'un ensemble d'outils numériques destinés à simuler différents aspects des interactions vagues-structure appliquées à l'exploitation des systèmes de récupération de l'énergie des vagues (SREV). Elle a été réalisée dans le cadre du projet ANR Monacorev (projet ANR11-MONU-018-01, 2012-2015).L'objectif est de pouvoir traiter la question des interactions à l'échelle d'une ferme de SREVs (≈ 1 km), et d'étudier l'impact d'une ou plusieurs fermes de SREVs à l'échelle régionale (≈ 10km) sur le champ de vague total. Des méthodes de modélisation et de simulation adaptées sont développées pour chacune de ces deux échelles. Jusqu'à présent, les interactions entre les SREVs étaient bien souvent étudiées en considérant que le fond était plat (l'influence d'un fond variable sur le champ de houle au niveau de la ferme étant alors jugé négligeable), ce qui permet de calculer facilement et rapidement le champ de vagues et les interactions grâce à l'utilisation de la théorie linéaire potentielle. Une application pratique de cette méthode est le calcul du rendement d'une ferme de SREVs, et l'optimisation de leurs positions relatives au sein d'un parc. Dans le cadre de la théorie linéaire, cette thèse propose une méthodologie de couplage originale entre un code de tenue à la mer (Aquaplus) et un code de propagation de la houle en zone côtière (Artemis), laquelle a été développée et qualifiée. Les simulations réalisées montrent que, pour une configuration de ferme de SREVs donnée, on ne peut pas toujours négliger les effets de la bathymétrie. Par exemple, la présence d'une plage de pente 10% au large d'une ferme de SREV peut modifier la hauteur des vagues de manière significative, et affecter ainsi le rendement de la ferme de manière significative par rapport au cas où le fond est uniformément plat. A l'échelle côtière régionale, il est aussi intéressant de simuler et prédire l'impact de fermes de SREVs sur le champ de vagues. Pour des raisons d'efficacité, une approche à phases moyennées de modélisation des vagues a été privilégiée, fondée sur le code spectral d'états de mer Tomawac. La représentation des effets d'un SREV à travers l'utilisation d'un terme puits (concept permettant de soustraire au spectre d'énergie d'état de mer local l'énergie correspondant à celle absorbée par le SREV), bien qu'incomplète du fait que les effets de radiation/diffraction ne sont pas pris en compte, a été étudiée et testée. Une nouvelle méthodologie prenant en compte ces effets dans un code spectral est présentée ici et testée, avec l'objectif de pallier à ces limitations. Les discussions sur la validité de deux approches permettent d'esquisser des pistes de développements ultérieurs pour la représentation des fermes de SREV à l'échelle régionale / This thesis focuses on the development of a set of numerical tools to simulate different aspects of the wave-body interactions applied to the exploitation of wave energy converters (WEC). It was conducted under the ANR Monacorev project (project-ANR11 MONU-018-01, 2012-2015).The objective is to address the issue of the interactions at the scale of a farm of WECs (≈ 1 km), and to study the impact of one or more WEC farms at the regional scale (≈ 10km ) on the total wave field. Modeling and simulation methods adapted for each of these two scales are developed. Until now, the interactions between WECs was often studied by considering that the bottom was flat (the influence of a variable bathymetry on the wave field at the farm site being considered to be negligible), allowing to easily and quickly calculate the wave field and interactions through the use of linear potential theory. A practical application of this method is the yield estimation for a WEC farm and the optimization of the WEC position within a park. In the framework of the linear theory, this thesis proposes an original coupling methodology between a seakeeping (Aquaplus) and a wave propagation code in coastal areas (Artemis), which was developed and qualified. Simulations show that, for a given WEC farm configuration, effects of the bathymetry cannot systematically ignored. For example, the presence of a 10% slope close to a WEC farm can significantly modify the wave height, and thus affect the performance of the farm by several percent compared to the case with a uniformly flat bottom. At the regional coastal scale, it is also interesting to simulate and predict the impact of WEC farms on the wave field. At this scale, for efficiency reasons, a phase-averaged simulation of waves was preferred, based on the sea state spectral code TOMAWAC. The representation of the effects of a WEC through the use of a sink-term (concept for subtracting the energy equivalent to that absorbed by the WEC to the sea state energy spectrum), though incomplete due to the fact that the scattering effects are not taken into account, has been studied and tested. A new methodology taking into account these effects in a spectral code is presented here and tested with the aim to overcome these limitations. Discussions on the validity of these approaches allow us to propose possible future developments for the modeling of WEC farm at the regional scale

Interactions vagues-Structure

Modélisation des vagues

Théorie potentielle

Approximation champ lointain

Terme puits

Wave Energy Converter (WEC)

Wave modeling

Potential theory

Far-Field approximation

Sink term

Wave-Body interactions

Modelling and Simulation of a Power Take-off in Connection with Multiple Wave Energy Converters

Ghodrati, Ashkan, Rashid, Ahmed

January 2014

The objective of this thesis is to develop a model that will integrate multiple buoys to a power take-off hub. The model will be derived using a time domain analysis and will consider the hydraulic coupling of the buoys and the power take-off. The derived model is reproduced in MATLAB in order to run simulations. This will give possibility to conduct a parameter study and evaluate the performance of the system. The buoy simulation model is provided by Wave4Power (W4P). It consists of a floater that is rigidly connected to a fully submerged vertical (acceleration) tube open at both ends. The tube contains a piston whose motion relative to the floater-tube system drives a power take-off mechanism. The power take-off model is provided by Ocean Harvesting Technologies AB (OHT). It comprises a mechanical gearbox and a gravity accumulator. The system is utilized to transform the irregular wave energy into a smooth electrical power output. OHT's simulation model needs to be extended with a hydraulic motor at the input shaft. There are control features in both systems, that need to be connected and synchronized with each other. Another major goal within the thesis is to test different online control techniques. A simple control strategy to optimize power capture is called sea-state tuning and it can be achieved by using a mechanical gearbox with several discrete gear ratios or with a variable displacement pump. The gear ratio of the gear box can be regulated according to a 2D look up table based on the average wave amplitude and frequency over a defined time frame. The OHT power take-off utilizes a control strategy, called spill function, to limit the excess power capture and keep the weight accumulator within a span by disengaging the input shaft from the power take-off. This is to be modified to implement power limitation with regulation of the gear ratio of the gearbox. / +46736290781

Wave power

power take-off

wave energy converter

weight accumulator

power capture control

planetary gearbox

modeling and simulation

Social Sciences Interdisciplinary

Mechanical Engineering

Maskinteknik

Elektroteknik och elektronik

Modélisation de fermes de systèmes houlomoteurs : effets d’interactions entre systèmes à l’échelle de la ferme et impact sur le climat de vagues à l'échelle régionale / Numerical modeling of arrays of wave energy converters : interaction effects between units at the scale of an array and impact on wave climatology at the regional scale

Charrayre, François

17 September 2015

Cette thèse porte sur le développement d'un ensemble d'outils numériques destinés à simuler différents aspects des interactions vagues-structure appliquées à l'exploitation des systèmes de récupération de l'énergie des vagues (SREV). Elle a été réalisée dans le cadre du projet ANR Monacorev (projet ANR11-MONU-018-01, 2012-2015).L'objectif est de pouvoir traiter la question des interactions à l'échelle d'une ferme de SREVs (≈ 1 km), et d'étudier l'impact d'une ou plusieurs fermes de SREVs à l'échelle régionale (≈ 10km) sur le champ de vague total. Des méthodes de modélisation et de simulation adaptées sont développées pour chacune de ces deux échelles. Jusqu'à présent, les interactions entre les SREVs étaient bien souvent étudiées en considérant que le fond était plat (l'influence d'un fond variable sur le champ de houle au niveau de la ferme étant alors jugé négligeable), ce qui permet de calculer facilement et rapidement le champ de vagues et les interactions grâce à l'utilisation de la théorie linéaire potentielle. Une application pratique de cette méthode est le calcul du rendement d'une ferme de SREVs, et l'optimisation de leurs positions relatives au sein d'un parc. Dans le cadre de la théorie linéaire, cette thèse propose une méthodologie de couplage originale entre un code de tenue à la mer (Aquaplus) et un code de propagation de la houle en zone côtière (Artemis), laquelle a été développée et qualifiée. Les simulations réalisées montrent que, pour une configuration de ferme de SREVs donnée, on ne peut pas toujours négliger les effets de la bathymétrie. Par exemple, la présence d'une plage de pente 10% au large d'une ferme de SREV peut modifier la hauteur des vagues de manière significative, et affecter ainsi le rendement de la ferme de manière significative par rapport au cas où le fond est uniformément plat. A l'échelle côtière régionale, il est aussi intéressant de simuler et prédire l'impact de fermes de SREVs sur le champ de vagues. Pour des raisons d'efficacité, une approche à phases moyennées de modélisation des vagues a été privilégiée, fondée sur le code spectral d'états de mer Tomawac. La représentation des effets d'un SREV à travers l'utilisation d'un terme puits (concept permettant de soustraire au spectre d'énergie d'état de mer local l'énergie correspondant à celle absorbée par le SREV), bien qu'incomplète du fait que les effets de radiation/diffraction ne sont pas pris en compte, a été étudiée et testée. Une nouvelle méthodologie prenant en compte ces effets dans un code spectral est présentée ici et testée, avec l'objectif de pallier à ces limitations. Les discussions sur la validité de deux approches permettent d'esquisser des pistes de développements ultérieurs pour la représentation des fermes de SREV à l'échelle régionale / This thesis focuses on the development of a set of numerical tools to simulate different aspects of the wave-body interactions applied to the exploitation of wave energy converters (WEC). It was conducted under the ANR Monacorev project (project-ANR11 MONU-018-01, 2012-2015).The objective is to address the issue of the interactions at the scale of a farm of WECs (≈ 1 km), and to study the impact of one or more WEC farms at the regional scale (≈ 10km ) on the total wave field. Modeling and simulation methods adapted for each of these two scales are developed. Until now, the interactions between WECs was often studied by considering that the bottom was flat (the influence of a variable bathymetry on the wave field at the farm site being considered to be negligible), allowing to easily and quickly calculate the wave field and interactions through the use of linear potential theory. A practical application of this method is the yield estimation for a WEC farm and the optimization of the WEC position within a park. In the framework of the linear theory, this thesis proposes an original coupling methodology between a seakeeping (Aquaplus) and a wave propagation code in coastal areas (Artemis), which was developed and qualified. Simulations show that, for a given WEC farm configuration, effects of the bathymetry cannot systematically ignored. For example, the presence of a 10% slope close to a WEC farm can significantly modify the wave height, and thus affect the performance of the farm by several percent compared to the case with a uniformly flat bottom. At the regional coastal scale, it is also interesting to simulate and predict the impact of WEC farms on the wave field. At this scale, for efficiency reasons, a phase-averaged simulation of waves was preferred, based on the sea state spectral code TOMAWAC. The representation of the effects of a WEC through the use of a sink-term (concept for subtracting the energy equivalent to that absorbed by the WEC to the sea state energy spectrum), though incomplete due to the fact that the scattering effects are not taken into account, has been studied and tested. A new methodology taking into account these effects in a spectral code is presented here and tested with the aim to overcome these limitations. Discussions on the validity of these approaches allow us to propose possible future developments for the modeling of WEC farm at the regional scale

Interactions vagues-Structure

Modélisation des vagues

Théorie potentielle

Approximation champ lointain

Terme puits

Wave Energy Converter (WEC)

Wave modeling

Potential theory

Far-Field approximation

Sink term

Wave-Body interactions

Optimisation du dimensionnement d’une chaîne de conversion électrique directe incluant un système de lissage de production par supercondensateurs : application au houlogénérateur SEAREV / Sizing optimization of a direct electrical conversion chain including a supercapacitor-based power output smoothing system : application to the SEAREV wave energy converter

Aubry, Judicaël

03 November 2011

Le travail présenté dans cette thèse porte sur l'étude du dimensionnement d'une chaine de conversion électrique en entrainement direct d'un système direct de récupération de l'énergie des vagues (searev). Cette chaine de conversion est composée d'une génératrice synchrone à aimants permanents solidaire d'un volant pendulaire, d'un convertisseur électronique composé de deux ponts triphasés à modulation de largeur d'impulsion, l'un contrôlant la génératrice, l'autre permettant d'injecter l'énergie électrique au réseau. En complément, un système de stockage de l'énergie (batterie de supercondensateurs) est destiné au lissage de la puissance produite. Le dimensionnement de tous ces éléments constitutifs nécessite une approche d'optimisation sur cycle, dans un contexte de fort couplage multi-physique notamment entre les parties hydrodynamique et électromécanique. Dans un premier temps, l'ensemble génératrice-convertisseur, dont le rôle est d'amortir le mouvement d'un volant pendulaire interne, est optimisé en vue de minimiser le coût de production de l'énergie (coût du kWh sur la durée d'usage). Cette optimisation sur cycle est réalisée en couplage fort avec le système houlogénérateur grâce à la prise en compte conjointe de variables d'optimisation relatives à l'ensemble convertisseur-machine mais aussi à la loi d'amortissement du volant pendulaire. L'intégration d'une stratégie de défluxage, intéressante pour assurer un fonctionnement en écrêtage de la puissance, permet, dès l'étape de dimensionnement, de traiter l'interaction convertisseur-machine. Dans un second temps, la capacité énergétique du système de stockage de l'énergie fait l'objet d'une optimisation en vue de la minimisation de son coût économique sur cycle de vie. Pour ce faire, nous définissons des critères de qualité de l'énergie injectée au réseau, dont un lié au flicker, et nous comparons des stratégies de gestion de l'état de charge tout en tenant compte du vieillissement en cyclage des supercondensateurs dû à la tension et à leur température. Dans un troisième temps, à partir de données d'états de mer sur une année entière, nous proposons des dimensionnements de chaines de conversion électrique qui présentent les meilleurs compromis en termes d'énergie totale récupérée et de coût d'investissement. / The work presented in this thesis sets forth the study of the sizing of a direct-drive electrical conversion chain for a direct wave energy converter (SEAREV). This electrical chain is made up of a permanent magnet synchronous generator attached to a pendular wheel and a power-electronic converter made up of two three-phase pulse width modulation bridge, one controlling the generator, the other allowing injecting electrical energy into the grid. In addition, an energy storage system (bank of supercapacitors) is intended to smooth the power output. The sizing of all these components needs an operating cycle optimization approach, in a system context with strong multi-physics coupling, more particularly between hydrodynamical and electromechanical parts. At first, the generator-converter set, whose role is to damp the pendular movement of an internal wheel, is optimized with a view to minimize the cost of energy (kWh production cost). This optimization, based on torque-speed operating profiles, is carried out considering a strong coupling with the wave energy converter thanks to the consideration as design variables, some relatives to the generator-converter sizing but also some relatives to the damping law of the pendular wheel. In addition, the consideration of a flux-weakening strategy, interesting to ensure a constant power operation (levelling), allows, as soon as the sizing step, to deal with the generator-converter interaction. In a second step, the rated energy capacity of the energy storage system is being optimized with a view of the minimization of its economical life-cycle cost. To do this, we define quality criteria of the power output, including one related to the flicker, and we compare three energy managment rules while taking into account the power cycling aging of the supercapacitors due to the voltage and their temperature. In a third step, from yearly sea-states data, we provide sizings of the direct-drive electrical conversion chain that are the best trades-offs in terms of total electrical produced energy and economical investment cost.

Chaîne de conversion électrique

Cycle de fonctionnement

Énergie des vagues

Entraînement direct

Houlogénérateur direct

Lissage de production

Machine à aimants permanents

Supercondensateurs

Permanent magnet synchronous machine

Power output smoothing

Sizing optimization

Supercapacitors

Wave energy converter

Design and layout of power conversion chain for a wave energy converter

Nithin Jose, Madassery

January 2017

Wave energy has the potential to provide an energy resource in this challenging energyenvironment. Wave energy converters are devices used to extract this energy and convertit into electricity. Wave Carpet is an example of such a novel wave energy converters andin its final form, it consists of a submerged membrane which covers an arbitrarily largearea above the sea floor. Incident waves create a pressure difference between the upper andlower surfaces, which triggers an up-and-down movement. The power take-off attached tothe surfaces serve to restrict this movement and thereby extract hydraulic power which isconverted to electricity.The Wave Carpet, is a type of wave energy converter that is beingdeveloped at University of California Berkeley′s Theoretical and Applied Fluid DynamicsLaboratory (TAFLab).The thesis aims at modeling and designing the different power conversion chainof the entire wave energy converter device. The process of energy conversion that yieldsthe required electrical energy for connecting a wave energy converter to an electricalnetwork is termed as the power conversion chain. A detailed electro-mechanical modelof the wave energy converter system connected to power grid is developed in theMatlab/SIMULINK environment and its corresponding generator and hydraulic controlstructure is implemented. The simulation response of the wave energy converter alongwith the power conversion chain is investigated. / Vågenergi har potential att bli en energiresurs i en utmanande energimiljö. Vågkraftverkär maskiner som används till att utvinna denna energi och omvandla den till elektricitet.Wave Carpet är ett exempel på ett vågkraftverk som i sitt slutglitiga stadie bestårav ett nedsänkt membran som täcker ett godtyckligt stort område ovanför sjöbotten.Inkommande vågor skapar en tryckskillnad mellan den övre och nedre ytan som gerupphov till en lodrätt rörelse. De mekaniska armarna kopplade till membranet bromsardenna rörelse och kan genom hydraulik omvandla bromsenergin till elektricitet. The WaveCarpet är en typ av vågkraftverk som utvecklas vid University of California Berkeley′sTheoretical and Applied Fluid Dynamics Laboratory (TAFLab).Uppsatsen syftar till att modellera och designa effektomvandlingskedjan i ett sådantvågkraftverk. Energiomvandlings processen som ger upphov till elektriciteten via ettvågkraftverk är benämnt som effektomvandlingskedjan. En detaljerad elektro-mekaniskmodell över ett vågkraftverksystem kopplat till ett elnät med motsvarande generator ochhydraliska regulatorer är utvecklad i Matlab/Simulink miljön. Simuleringsresultaten fråndet modellerade vågkraftverket undersöks tillsammans med effektomvandlingskedjan.

Permanent-magnet synchronous generator

Power conversion chain

Power take off

SimHydraulics

Wave energy converter

Wave energy

Permanentmagnet synkrongenerator

Effektomvandlingskedjan

Kraftuttag

SimHydraulics

Vågenergiomvandlaren

Vågenergi

Elektroteknik och elektronik

Comparison of control strategies for Peltonturbines in Wave Energy Converters / Jämförelse av styrstrategier för Peltonturbiner i vågenergiomvandlare

HAMILTON, PHILIP, SJÖGREN, ANDREAS

January 2021

Wave energy is a promising renewable resource with a higher energy density than both wind and solar. Waves can travel thousands of kilometers with minimal energy loss, making them more reliable than the previously mentioned alternatives. A device that utilizes wave energy to generate electricity is calleda Wave Energy Converter. The converter studied in this thesis is a non-resonant point absorber, a floating device that absorbs energy through its displacement in the water. An incident wave approaching the converter combined with a latching strategy transforms the wave into a water jet, which emerges as a pulse wave and varies from zero to maximum velocity. The kinetic energy of the water jet gets converted to electricity through a Pelton turbine and a permanent magnet synchronous motor that acts as a generator. The thesis investigates three generator velocity control strategies and two deadtime strategies and aims to answer which strategy yields the best efficiency for the selected wave fields. The strategies strive to maximize the efficiency of the Pelton turbine while minimizing the frictional and electrical losses. The first velocity control approach relies on historical data and computes the average based on the previous wavefield. The second approach maintains a predetermined turbine velocity based on the average jet velocity of each incident wave. Lastly, the third strategy continuously adapts the speed during each jet pulse to maximize the Pelton turbine efficiency. The dead-time strategies refer to the approaches employed between waves. The first approach maintainsa constant generator velocity, reducing the necessary acceleration to match the next incident wave. The second approach freewheels the generator, allowing it to decelerate due to friction losses. During the deceleration, the generator draws no current, but as the next wave arrives it must instead accelerate. Consequently, drawing more current but during a shorter period. The results reveal that there is no significant difference between the two deadtime strategies, but there is a significant difference between the velocity control strategies. Furthermore, the results illustrate the effectiveness of the local averaging method and the adaptive control method, which result in the highest system efficiency. / Vågenergi är en lovande energiresurs som har högre energidensitet än både vind- och solkraft. Vågor kan färdas tusentals kilometer med minimal energiförlust,vilket gör dem mer tillförlitliga än de tidigare nämnda alternativen. En anordning som kan nyttja vågors energi för att generera elektricitet kallas för vågenergiomvandlare. Omvandlaren som studerats i detta arbete är en icke-resonant punktabsorbent,vilket är en flytande anordning som absorberar energi genom dess förflyttning i vattnet. När en kommande våg närmar sig omvandlaren transformeras vågen till en vattenstråle, som framträder som en pulsvåg och varierar mellan noll och maxhastighet, via en styrstrategi vid namn ”latching”. Den kinetiska energin från vattenstrålen omvandlas till elektrisk energi via en Peltonturbin och en synkronmotor som agerar som generator. Det här arbetet undersöker tre hastighetsstyrstrategier samt två mellantidsstrategier för generatorn, och ämnar besvara vilken som är den mest effektiva strategin för en uppsättning vågor. Målet med dessa strategier är att maximera effektiviteten hos Peltonturbinen medan friktions- samt elektriska förluster minimeras. Den första hastighetsstyrstrategin håller en konstant hastighetbaserad på ett medelvärde från ett tidigare vågfält. Den andra strategin hålleren konstant hastighet, vilken anpassas till varje inkommande våg. Den tredje strategin anpassar hastigheten kontinuerligt under pulsvågen för att maximera turbineffektiviteten. Med mellantidsstrategierna menas de styrstrategier som nyttjas mellan vattenpulserna. I den första mellantidsstrategin körs generatorn som motor och håller konstant hastighet, vilket minskar de nödvändiga accelerationerna för att möta kommande vågs referenshastighet. Den andra strategin låter generatorn frihjula, vilket gör att hastigheten faller på grund av friktionsförluster. Under hastighetsminskningen drar generatorn ingen ström, men den måste då istället accelerera när kommande våg anländer. Detta innebär att generatorn kommer att dra mer ström, men under en kortare period. Resultaten avslöjade att det inte var någon signifikant skillnad mellan de två mellantidsstrategierna och att det var en signifikant skillnad mellan hastighetsstyrstrategierna. Resultatet visade att de två metoderna med variabel hastighet gav högre systemeffektivitet än metoden med konstant hastighet.

Permanent Magnet Synchronous Generator

Synchronous Motor

Wave Energy Converter

Pelton Turbine

Velocity Control Strategies

Dead-time Strategies

Cascaded Control

Permanentmagnetgenerator

Synkrongenerator

Synkronmotor

Vågenergiomvandlare

Peltonturbin

Hastighetskontrollstrategier

Mellantidsstrategier

Kaskadreglering

Engineering and Technology

Teknik och teknologier

Estudo numérico de unidade flutuante monocoluna para conversão de energia de ondas do mar. / Numeric study of monocolumn floating unit for sea wave energy conversion.

Rocha, Thiago Peternella

16 October 2017

O uso contínuo de combustíveis fósseis já se mostrou deletério há anos, além de ser um meio energético finito. Por este motivo, a demanda atual e futura por sistemas de energia limpa é grande. Muito embora já existam diversas estruturas dedicadas a extrair energia do mar, o conceito em que se pretende trabalhar é inovador e de tecnologia nacional. Este tema foi desenvolvido inicialmente em uma abordagem teórica pelo então aluno de engenharia naval Daniel Prata Vieira e sua colega Ana Luísa Orsolini, como Trabalho Final do curso de Engenharia Naval e Oceânica da Escola Politécnica da USP, orientados pelo Prof. Dr. André Luis Condino Fujarra. Vieira & Orsolini (2011) [1] abordaram de uma forma diferente o tema de geração de energia por ondas do mar, trazendo à tona o uso da já consagrada plataforma monocoluna - protótipo que rendeu diversos prêmios de inventor do ano da Petrobrás, além de patente, ao Tanque de Provas Numérico, laboratório do departamento de engenharia naval da POLI-USP. O trabalho dos alunos Daniel e Ana também foi reconhecido nacionalmente recebendo o Prêmio Petrobras de Tecnologia 2011 no tema de Tecnologia de Energia. A continuação do trabalho consiste em levar a fundo alguns pontos importantes relacionados ao dimensionamento da plataforma para otimizar a geração de energia através do movimento relativo entre ela e um corpo flutuante interno ao seu moonpool. O objetivo do trabalho é definir melhores geometrias através da parametrização das dimensões principais e da utilização de métodos numéricos num estudo mais detalhado e aprofundado. O método de desenvolvimento leva em conta todos os fatores que influenciam na dinâmica do sistema como a hidrodinâmica de dois corpos (plataforma e corpo interno flutuante) e a dinâmica do gerador de energia (tipo de gerador e seu impacto no amortecimento do sistema global). / The continued use of fossil fuels has proved harmful for years, besides being a means finite energy. For this reason, the current and future demand for clean energy systems are great. Although there are already several structures dedicated to extracting energy from the sea, the concept on which it intends to work is innovative and with local technology. This theme has been already developed in a theoretical approach by the student of naval engineering Daniel Prata Vieira and his classmate Ana Luisa Orsolini, such as Final Paper Course of Naval Architecture and Ocean Engineering from the Escola Politécnica of USP, directed by Prof. Dr. André Luis Condino Fujarra. Vieira \\& Orsolini (2010) [1] studied in a different way the theme of energy generation from ocean waves, bringing up the use of already established monocolumn platform - prototype that earned several inventor of the year from Petrobras awards, besides patent, to the Numerical Offshore Tank, laboratory of the Naval Engineering Department of Poli - USP. The work of students Daniel and Ana was also recognized nationally getting the Petrobras Technology Award 2011 in the Energy Technology theme. The continuation of this work is to bring the background some important points related to platform design to optimize power generation through the relative motion between it and an internal floating body into moonpool. The objective is to define best geometries through the parameterization of the key dimensions and the use of numerical methods in a more detailed and in-depth study. The development method takes into account all the factors that influence the dynamics of the system such as the hydrodynamics of two bodies (platform and floating internal body) and the dynamics of the generator (type of generator and its impact on the damping of the global system).

Alternative sources

Conversores elétricos

Fontes alternativas de energia

Geração de energia elétrica

Large absorber

Marine energy

Monocolumn platform

Ondas (Oceanografia)

Oscillating body System

Point absorber

Power generation

Renewable energy

Sea energy

Sea wave energy Converter

Two-body heaving System.

Wave energy

Wave energy Devices