On using simulation to model the installation process logistics for an offshore wind farm

The development of offshore wind farms (OWFs) in Europe is progressing to sites which are characteristically further from shore, in deeper waters, and of larger scale than previous sites. A consequence of moving further offshore is that installation operations are subject to harsher weather conditions, resulting in increased uncertainty in relation to the cost and duration of any operations. Assessing the comparative risks associated with different installation scenarios and identifying the best course of action is therefore a crucial problem for decision makers. Motivated by collaboration with industry partners, we present a detailed definition of the OWF installation process logistics problem, where aspects of fleet sizing, composition, and vessel scheduling are present. This article illustrates the use of simulation models to improve the understanding of the risks associated with logistical installation decisions. The developed tool employs a realistic model of the installation operations and enables the effect of any logistical decision to be investigated. A case study of an offshore wind farm installation project is presented in order to explore the impact of key logistical decisions on the cost and duration of the installation, and demonstrates that savings of up to 50% can be achieved through vessel optimization

A reliability-and-cost-based fuzzy approach to optimize preventive maintenance scheduling for offshore wind farms

We study the preventive maintenance scheduling problem of wind farms in the offshore wind energy sector which operates under uncertainty due to the state of the ocean and market demand. We formulate a fuzzy multi-objective non-linear chance-constrained programming model with newly-defined reliability and cost criteria and constraints to obtain satisfying schedules for wind turbine maintenance. To solve the optimization model, a 2-phase solution framework integrating the operational law for fuzzy arithmetic and the non-dominated sorting genetic algorithm II for multi-objective programming is developed. Pareto-optimal solutions of the schedules are obtained to form the trade-offs between the reliability maximization and cost minimization objectives. A numerical example is illustrated to validate the model

Evaluation of the Impact of Weather-Related Limitations on the Installation of Offshore Wind Turbine Towers

Weather conditions have a significant impact on the installation of offshore wind turbines. The rules for installation set clear limits. These limits are usually based on estimations of various experts and not on real assumptions and measurements on-site. When wind speeds and wave heights are too high, work cannot be carried out, and this leads to delays and additional costs. Therefore, we have carried out a measurement campaign during the installation of rotor blades to investigate to which extent the limits can be adjusted by using a tuned mass damper. The results from the measurement campaign—specifically empirically derived significant wave height limits—are used in a discrete event simulation. This study simulates delays resulting from weather conditions. Based on this, the total installation costs are considered. The results of the measurement campaign show that a safe installation with the use of a damper is possible at wave heights of up to 1.6 m. With the discrete event simulation, it is possible to prove that 17.9% can be saved for the costs of the installation vessel. In addition, the wind farm could be erected 32 days faster. Thus, it can be stated that the use of a tuned mass damper simplifies the installation from a technical point of view and is economical

A reliability-and-cost-based fuzzy approach to optimize preventive maintenance scheduling for offshore wind farms

This is the author accepted manuscript. The final version is available from Elsevier via the DOI in this recordWe study the preventive maintenance scheduling problem of wind farms in the offshore wind energy sector which operates under uncertainty due to the state of the ocean and market demand. We formulate a fuzzy multi-objective non-linear chance-constrained programming model with newly-defined reliability and cost criteria and constraints to obtain satisfying schedules for wind turbine maintenance. To solve the optimization model, a 2-phase solution framework integrating the operational law for fuzzy arithmetic and the non-dominated sorting genetic algorithm II for multi-objective programming is developed. Pareto-optimal solutions of the schedules are obtained to form the trade-offs between the reliability maximization and cost minimization objectives. A numerical example is illustrated to validate the model.Recruitment Program of High-end Foreign Expert

An integrated operation and maintenance framework for offshore renewable energy

Offshore renewable devices hold a large potential as renewable energy sources, but their deployment costs are still too high compared to those of other technologies. Operation and maintenance, as well as management of the assets, are main contributors to the overall costs of the projects, and decision-support tools in this area are required to decrease the final cost of energy.\\ In this thesis a complete characterisation and optimisation framework for the operation, maintenance and assets management of an offshore renewable farm is presented. The methodology uses known approaches, based on Monte Carlo simulation for the characterisation of the key performance indicators of the offshore renewable farm, and genetic algorithms as a search heuristic for the proposal of improved strategies. These methods, coupled in an integrated framework, constitute a novel and valuable tool to support the decision-making process in this area. The methods developed consider multiple aspects for the accurate description of the problem, including considerations on the reliability of the devices and limitations on the offshore operations dictated by the properties of the maintenance assets. Mechanisms and constraints that influence the maintenance procedures are considered and used to determine the optimal strategy. The models are flexible over a range of offshore renewable technologies, and adaptable to different offshore farm sizes and layouts, as well as maintenance assets and configurations of the devices. The approaches presented demonstrate the potential for cost reduction in the operation and maintenance strategy selection, and highlight the importance of computational tools to improve the profitability of a project while ensuring that satisfactory levels of availability and reliability are preserved. Three case studies to show the benefits of application of such methodologies, as well as the validity of their implementation, are provided. Areas for further development are identified, and suggestions to improve the effectiveness of decision-making tools for the assets management of offshore renewable technologies are provided.European CommissionMojo Ocean Dynamics Ltd. T/A Mojo Maritime Lt

An optimisation model for scheduling the decommissioning of an offshore wind farm

An optimisation model is proposed for scheduling the decommissioning of an offshore wind farm in order to minimise the total cost which is comprised of jack-up vessel, barge (transfer) vessel, inventory, processing and on-land transportation costs. This paper also presents a comprehensive review of the strategic issues relating to the decommissioning process and of scheduling models that have been applied to offshore wind farms. A mathematical model using integer linear programming is developed to determine the optimal schedule considering several constraints such as the availability of vessels and planning delays. As the decommissioning problem is challenging to solve, a matheuristic approach based on the hybridisation of a heuristic approach and an exact method is also proposed to find near optimal solutions for a test set of problems. A set of computational experiments has been carried out to assess the proposed approach

Multi-objective optimization of the operation and maintenance assets of an offshore wind farm using genetic algorithms

The first author was funded by the Marie Curie Actions of the European Union’s Seventh Framework Programme FP7/2007- 2013/ under REA grant agreement number 607656 (OceaNet project) and by the industrial partner James Fisher Marine Services Ltd. Mojo Maritime (JFMS group) have provided access to Mermaid to support, and for integration with, this research. This work is also funded by the EPSRC (UK) grant for the SuperGen United Kingdom Centre for Marine Energy Research (UKCMER) [grant number: EP/P008682/1]This is the author accepted manuscriptThis paper explores the use of genetic algorithms to optimize the operation and maintenance (O&M) assets of an offshore wind farm. Three different methods are implemented in order to demonstrate the approach. The optimization problem simultaneously considers both the reliability characteristics of the offshore wind turbines and the composition of the maintenance fleet, seeking to identify the optimal configurations for the strategic assets. These are evaluated in order to minimize the operating costs of the offshore farm while maximizing both its reliability and availability. The considerations used for the application of genetic algorithms as an effective way to support the assets management are described, and a case study to show the applicability of the approach is presented. The variation of the economic performance indicators as a consequence of the optimization procedure are discussed, and the implementation of this method in a wider computational framework for the O&M assets improvement introduced.European CommissionMojo Ocean Dynamics Ltd. T/A Mojo Maritime LtdEPSRC (UK) grant for the SuperGen United Kingdom Centre for Marine Energy Research (UKCMER

Strategic optimization of offshore wind farm installation

This work describes logistical planning of offshore wind farm (OWF) installation through linear programming. A mixed integer linear programming (MILP) model is developed to analyze cost-effective port and vessel strategies for offshore installation operations. The model seeks to minimize total costs through strategic decisions, that is decisions on port and vessel fleet and mix. Different vessels, ports and weather restrictions over a fixed time horizon are considered in the model. Several deterministic test cases with historic weather data are implemented in AMPL, and run with the CPLEX solver. The results provide valuable insight into economic impact of strategic decisions. Numerical experiments on instances indicate that decision aid could be more reliable if large OWFs are considered in fractionated parts, alternatively by developing heuristics.acceptedVersio

Computational methods and parallel strategies in dynamic decision making

Cada uno de estos objetivos han sido tratados en un capítulo independiente de esta tesis. En el segundo capítulo, un modelo de programación estocástica es presentado para un problema práctico de planificación de producción de un producto perecedero en un horizonte de tiempo finito. Una política estática es estudiada para el modelo. Tal política ha demostrado ser óptima asumiendo una estrategia de incertidumbre estática, que es considerada para instancias con un tiempo de espera largo. El tercer capítulo trata el uso de computación paralela para los algoritmos desarrollados en el capítulo previo. Dos implementaciones fueron desarrolladas para plataformas heterogéneas: una versión multi-GPU usando CUDA y una versión multinúcleo usando Pthreads y MPI. Para la primera implementación la simulación de Monte Carlo (la tarea más costosa) es paralelizada. La versión multinúcleo mostró una buena escalabilidad, una vez tratada la carga no balanceada entre los procesadores. El cuarto capítulo trata la efectividad de heurísticas para un problemas de tamaño de lote de productos perecederos similar. La clásica heurística de Silver es extendida para productos perecederos y se presentan variantes del procedimiento: una analítica y una basada en simulación. Los resultados de la heurística son comparados con las soluciones óptimas dadas por un modelo SDP generado para el problema, mostrando que los costes de las heurísticas son se presentan, de media, un 5% sobre el coste óptimo para la estrategia basada en simulación y un 6% para la aproximación analítica. En el quinto capítulo, se presenta un modelo MILP para seleccionar la flota de embarcaciones óptima para el mantenimiento de un parque eólico marino. El modelo se presenta como un problema de dos niveles, seleccionando la flota optima en el primer nivel y optimizando la programación de las operaciones, usando dicha flota, en el segundo. Dado que el modelo es determinístico, como otros en la literatura que aspiran a resolver problemas con un horizonte temporal largo usando periodos cortos, el sexto capítulo trata la cuestión de cómo la anticipación de los eventos estocásticos como los fallos en las turbinas o las condiciones meteorológicas afectan la decisión de la flota de embarcaciones óptima. Este capítulo presenta una heurística que ilustra este efecto.Esta tesis analiza aplicaciones de toma de decisiones dinámica para un conjunto de problemas. Pueden diferenciarse dos líneas principales. La primera trata problemas de gestión de la cadena de suministro para productos perecederos, mientras que la segunda estudia el diseño de flotas de embarcaciones para realizar labores de mantenimiento en parques eólicos marinos. Los modelos de inventario para productos perecederos estudiados en esta tesis consideran un único producto, única localización de suministro y una planificación de producción sobre un horizonte de tiempo finito. El problema de toma de decisiones para programar las operaciones de mantenimiento en parques eólicos marinos es tratado como un problema de cadena de suministro: la instalación requiere programar operaciones de mantenimiento y atender los fallos en turbinas durante el horizonte planificado. Una flota de embarcaciones tiene que ser seleccionada para realizar estas operaciones. Para este conjunto de problemas, las decisiones no son solo dinámicas, sino que además se realizan bajo incertidumbre. Los principales objetivos de esta tesis son los siguientes: (1) estudiar que políticas de pedido son las más apropiadas para los problemas de tamaño de lote? ¿En qué casos una política de pedido da una solución óptima?; (2) analizar el efecto del uso de computación paralela para mejorar el rendimiento de los algoritmos derivados para diseñar políticas para problemas de tamaño de lote de productos perecederos; (3) explorar como de efectivas pueden ser las heurísticas para problemas de toma de decisiones dinámica sobre tamaño de lote de productos perecederos; (4) elaborar un modelo MILP para seleccionar una flota de embarcaciones para realizar las operaciones de mantenimiento en parques eólicos marinos; y (5), diseñar una heurística para programar las operaciones de mantenimiento en parques eólicos marinos considerando fallos en turbinas e incertidumbre meteorológica