1.1. Background
Wildfires and excessive floodings have been seasonal climatic changes across the globe in the past decade. The need for clean energy to fight against the climate changes observed as a result of excessive greenhouse emissions over the years is driving the development of the offshore wind sector. This drive is pushing the exploitation of rich wind resources in deep waters with water depth greater than 60 m, requiring a deviation from the commercialized fixed-bottom foundation offshore wind technology. Resolving the issue of exploiting rich wind resources requires the use of floating foundation offshore wind technology that satisfies stability and durability requirements in any environmental conditions. With more than three-quarters of the world’s offshore wind resource potential available in waters deeper than 60 m along the coastline of many countries, the potential for fixed-bottom offshore wind systems becomes limited [
1]. This highlights the need for FOWT technology in order to see a true global growth in clean technology to contribute to the reduction in greenhouse emissions.
Mega-Watts’ (MW) scale floating technologies have only been tested in the last ten years through demonstration and pilot projects in both Europe and Asia. With the completion of some demonstration projects, FOWT technology is currently in the pre-commercial phase, with a shift in emphasis moving towards larger power capacity turbine schemes [
1]. It is anticipated that, by 2026, FOWT system deployment will move into the commercial phase, with yearly installations surpassing 1 GW–a milestone achieved by fixed offshore wind in 2010 [
2].
The concept of the floating offshore wind turbine was conceived in the 1970s [
3]. Despite its early conception, FOWT is still in the pre-commercial stage, leaving the fixed-bottom foundation/platform as the dominant technology in the OWT sector [
4]. FOWT foundation technology complements its fixed-bottom foundation counterpart as it offers capabilities for setting up the FOWT system offshore in deep waters while ensuring less invasive actions on the seabed which potentially present a less expensive technology [
5]. FOWT technology provides the capability to move further offshore to exploit better wind resources while also limiting visual impact from land and moving away from competing with other users of the sea [
6]. Additionally, due to less-invasive construction methods on the seabed than fixed-bottom designs, floating foundations typically provide environmental advantages over them [
7]. The world’s forecast growth of floating offshore wind was 17MW in 2020 to 6.5 GW by 2030. A review of the forecast was conducted in 2021 with the forecast increased to 16.5 GW of floating offshore wind capacity by 2030 [
1], highlighting a significant interest in increasing the capacity of FOWT technology in reducing greenhouse emissions. The floaters required for offshore wind must provide adequate buoyancy to support the weight of the wind turbines and also have the capability to constrain its motion within allowable limits [
8].
Three main floating platform concepts (spar, semisubmersible and tension leg platform) from the oil and gas industry are the early adapters (early to market floaters) in the FOWT sector. The stabilization mechanisms of the three platforms highlighted are ballast, waterplane/buoyancy and mooring stabilization, respectively. As highlighted in Leimeister, et al. [
9], several floating solutions have currently been developed that are anticipated to be appropriate and considerably financially viable in depths greater than 60 m. These new floating solutions still adapt the stability mechanisms used in the early-adapter floaters from the oil and gas sector.
The ballast-stabilized spar requires a large ballast that is deep at the bottom of the floater to move the center of gravity of the system below the center of buoyancy in order to provide a restoring moment or stabilizing righting moment which counteracts the inclining moments. In the waterplane area or buoyancy-stabilized semi-submersible, a large second moment of waterplane area with respect to the rotational axis creates the restoring moment to counteract against the rotational displacement.
The mooring-stabilized TLP utilizes high-tension mooring lines to generate the restoring moments to counteract the effect of any inclining moment on the structure. The choice of the platform used for a FOWT system will also depend on elements like water depth, localization potential, local infrastructure and various turbine designs. As a result, the market will likely adjust to changing situations rather than rationalize around a single sort of floating platform [
1].
The average CAPEX of a floating platform is higher than that of a fixed-bottom platform. As highlighted in [
10], the best rate value CAPEX for a fixed-bottom OWT is 2435 k€/MW while for spar, semi-sub and TLP FOWTs, the CAPEX are estimated at 3025 k€/MW, 3080 k€/MW and 2970 k€/MW, respectively. The floating substructure of a reference wind power plant accounts for approximately 29.5% of the CAPEX for the project, in contrast to 13.5% for a fixed-bottom reference project [
11]. These average values can be significantly higher or lower depending on the floater type employed and will significantly impact the profitability of the project. It is expected to see innovation in design, construction, operation and maintenance as the industry evolves to facilitate the building and operation of larger FOWT projects. The construction of FOWT systems can be in ports or sheltered waters making use of specialized vessels. Major maintenance and repair activities might also be carried out away from the site using the innovative “tow-to-port” maintenance capability. Continuous innovation in design is expected to yield new technologies and products capable of supporting better mooring and anchor solutions, deep water substations and dynamic cabling, management of FOWT system’s response to environmental conditions and sea-states and the design of floating platforms.
Bringing the cost of floaters/platforms used in the FOWT system down to the level of fixed-bottom platforms needs extensive developmental process and ideas exploration. Some of the processes and ideas that can be explored in driving down the cost of FOWT systems are:
Geometric shape parametric design, analysis and optimization of the FOWT platform [
12,
13,
14,
15];
Upscaling design platform to fit with larger turbines [
16,
17,
18];
Multidisciplinary design analysis and optimization of all components within the FOWT system (Turbine, tower, platforms, mooring lines and anchors) [
19,
20,
21];
Provision of government subsidy to floating wind projects in the precommercial stage to add economic value until the FOWT technology becomes cost-competitive with the fixed-bottom OWTs [
22].
Currently, most floaters in offshore wind are modeled after the conventional oil and gas stability mechanism of ballast–spar, waterplane area–semi-submersible and mooring–Tension Leg Platform. This work is addressing a gap of platform shape alteration using the spar as a case study and assessing the economic impact of the optimized shape in a FOWF. This study has the potential to identify optimal novel design shapes within a large design space in a reduced computational time before detailed hydrodynamic response analyses are conducted with time domain tools.
1.2. B-Spline Curve
The uniqueness of this study lies in the use of a B-spline polynomial curve to model a spar platform within an optimization framework. The use of B-spline has been extensively used in other sectors like the automobile and oil and gas [
23,
24]. B-spline’s notable use in modeling within the FOWT sector is seen in the work of [
25] where it was used in describing the circumferential T-ring stiffeners within the hull of spar platform to reduce the number of design variables and corresponding computational time.
The novelty of using the B-spline technique to model a FOWT platform lies in its capacity to provide a highly flexible and smooth representation of complex geometric shapes. B-splines offer a parametric approach that allows for precise control over the shape of the model, enabling designers to efficiently explore and optimize various design configurations within the specified design space.
This work is exploring the use of B-spline to model a spar FOWT platform within an optimization due to some of its unique properties detailed in [
23] and highlighted below.
A B-spline curve has local propagation properties which make it possible to locally alter the shape of the design rather than altering the global shape as is the case with most modeling curves like the Bezier curve. A given control point influences 1 or 2 or n curve segments. This ensures B-spline localized shape control. This property is important as it gives the designer the capability to alter different segments of the design, including altering the shape geometry as shown in
Section 3.2;
The number of segments in a B-spline curve is derived from the degree and the number of control points in the curve, i.e., the number of segments is n − k + 2 where n is the number of control points and k is the degree/order of the curve;
The continuity of a B-spline curve can go beyond the C2/curvature continuity to ensure a higher level of smoothness of the curve. A B-spline curve is C(k−2) continuous;
A B-spline curve is invariant under affine transformation;
A B-spline curve has partition of unity properties.
B-spline is an essential design approach within this framework as it allows designers to modify the positions of control points to deform the shape of the B-spline curve or surface, enabling the exploration of different design variations while maintaining smoothness and continuity. This level of adaptability and control can be potentially advantageous in the dynamic and challenging environment of FOWT platforms, where intricate shapes and structural considerations are crucial. The B-spline technique’s capability for thorough design space exploration and its ability to balance geometric complexity with manageability contributes to its novelty in enhancing the design, analysis and optimization processes for a spar FOWT platform in this study.
Details of the B-spline equation and the optimization problem of this study are presented in
Section 3.2. The main aim of this study is to investigate the economic implications of use of the local propagation property of B-spline to alter the geometric shape of a spar FOWT within a design, analysis and optimization framework on a 30 MW FOWF and also the cumulative effect of this bespoke approach and economies of scale on a 60 MW FOWF.
1.3. FOWT Techno-Economic Feasibility-Overview
At the turn of the millennium, the total installed costs for offshore wind farms were initially evaluated based on the costs of existing shallow-water farms and extrapolated to deeper waters for deep-water offshore farms [
26]. The extrapolation resulted in increased costs of foundations, grid connection and installation. The design approach for these new offshore wind farms resulted in a notable trend. It led to an increase in the average cost of offshore wind installations, which rose from 2300 €/kW in 2000 to a peak of 5000 €/kW during the period from 2011 to 2014. However, starting in 2015, there was a positive shift in this trend. The total costs of FOWFs began to decrease, ultimately reaching 4000 €/kW in 2018 [
7,
26,
27].
The predicted cost for FOWFs is expected to decrease, according to recent studies, primarily due to technological advancements. These allow capacity factors to rise while lowering overall installation and maintenance costs [
26]. Additionally, the rise in this technology’s competitiveness can also be efficiently improved by the following:
Aerodynamics, Hydrodynamics, Servodynamics, Elastodynamics (AHSE) optimization within a MDAO framework and adequate use of shape parameterization technique with an optimization algorithm to optimize platforms in accordance with specified design objectives and constraints;
Platform upscaling techniques to bigger and heavier turbines;
Increase in designers’ experience, which reduces project development costs and risks;
The increase in the industry maturity, bringing lower capital cost;
Presence of economies of scale across the value chain.
The future development of floating wind technology will benefit from accurate financial analyses sustaining the economic and technical value of FOWTs. Some of the techno-economic study on FOWTs are detailed herein.
A shape parameterization study of the FOWT platform was conducted by [
28] to alter the shape of a spar platform coupled to a 5 MW OC3 turbine, reducing the mass of the spar platform and leading to a reduction in the required cost of steel for manufacturing the spar platform. This study used a B-spline parameterization technique within a design analysis and optimization framework using a metaheuristic pattern search optimization algorithm to explore the design space and produce an optimal design. The optimal design in the study is a spar variant platform with altered shape and lower mass than the standard OC3 platform. The limitation in this study is that the cost of steel for the optimal spar was the only financial parameter to assess the economic feasibility of the FOWT system.
Ghigo et al. [
29] conducted a study on platform optimization and cost analysis in a floating offshore wind farm. This study focused on the choice of a floating platform that minimizes the global weight, in order to reduce the material cost, while ensuring buoyancy and static stability. Subsequently, the optimized platform is used to define a wind farm located near the island of Pantelleria, Italy in order to meet the island’s electricity needs. A sensitivity analysis to estimate the LCOE for different sites is presented, analyzing the parameters that influence it most, like Capacity Factor, Weighted Average Capital Cost (WACC) and number of wind turbines. The study concluded that the decrease in many Capex cost items and the evolution of the offshore wind market will make this technology even more competitive in a few years.
Ioannou, Liang, Jalón and Brennan [
11] conducted a preliminary parametric techno-economic study of offshore wind floater concepts. This study investigated through a parametric study the total mass and cost of three floater concepts: spar, barge and semi-submersible, particularly focusing on the material and manufacturing costs. A survey from floating offshore wind industry professionals was conducted to determine the manufacturing complexity factors’ values, which were used to calculate the manufacturing cost. The main conclusion of this work is that, given the specified conditions, steel-based semi-sub structures proved to be the most expensive configuration followed by spar as spar prices fall with higher draught values due to the reduction in ballast mass. The barge solution is the least expensive option of the three configurations. Also, the study highlighted that the risks and benefits of different configurations should also be considered, as they could lead to savings throughout the service life of the asset.
Castro-Santos, et al. [
30] presented an approach for evaluating the lifecycle costs of a combined or hybrid floating offshore renewable energy system like a FOWT. Their methodology expressly takes into account the life cycle stages, amongst which are concept generation and definition, design and development, manufacturing, installation, exploration, exploitation and decommissioning. It is a tool for strategic planning and decision-making, allowing for a better understanding of technical advancements and factors that could either expedite or slow down the growth of the FOWT sector. Their findings from two sites show that the exploitation, manufacturing and installation costs are the most important lifecycle costs on the LCOE, but the most important of the three costs could be site-dependent.
Martinez and Iglesias [
31] conducted an extensive study that mapped the LCOE for floating offshore wind in the European Atlantic. They emphasized the importance of understanding LCOE spatial variations to identify suitable areas for the development of FOWT technology. The study focused on floating semi-submersible platforms, presenting a comprehensive LCOE mapping across the European Atlantic. Accurate energy production estimates were obtained by combining hindcast wind data and an exemplary wind turbine’s power curve. The study revealed the lowest LCOE values (around 95 €/MWh) in wind-rich regions like Great Britain, Ireland, the North Sea and NW Spain. In contrast, higher LCOE values (approximately 125 €/MWh) were observed off Portugal and Norway, and significantly higher values exceeding 160 €/MWh were noted in the Gulf of Biscay and south of the Iberian Peninsula.
Filgueira-Vizoso et al. [
32] evaluated the technical and economic viability of floating offshore wind platforms. Their work defined an economic assessment approach for TLP platform-based offshore wind farms. Life-cycle costs were categorized into stages including conception, design, manufacturing, installation, exploitation and dismantling. Economic indicators like IRR, NPV, DPBP and LCOE were assessed based on cashflow. The study focused on a TLP platform designed by CENTEC, considering an 880 MW farm located along the European Atlantic Coast in the northwest region of Galicia, Spain. Eighteen case scenarios were analyzed, with varying electric tariffs and capital costs. The study underscored the impact of electric tariffs on economic indicators. The optimal outcome emerged for a tariff of EUR 150/MWh and a 6% cost of capital, yielding an IRR of 18.34%, NPV of EUR 2636.45 million, and DPBP of 8 years. The farm’s LCOE reached a minimum of EUR 54.33/MWh, rendering the platform economically feasible due to its IRR-surpassing capital costs.
Pham and Shin [
33] introduced a novel conceptual design for a spar-type platform, intended to accommodate a 5 MW offshore wind turbine. This innovative concept effectively addresses challenges associated with the OC3-hywind model, notably the elevated nacelle acceleration and tower-base bending moment. This achievement is accomplished through the incorporation of an open moonpool positioned at the platform’s center. By leveraging the water column within the moonpool, the mass and inertia of the entire wind system are augmented along the x and y axes. By appropriately sizing the moonpool diameter, it becomes possible to mitigate nacelle acceleration and tower-base bending moment concerns.
Campos et al. [
34] presented a novel approach to achieving a cost-efficient offshore wind turbine floating platform. This concept revolves around a monolithic floating spar buoy design. The innovation lies in the integration of both the tower and floater components as a seamless, continuous concrete structure. This concept promises significant cost savings, not only during the construction phase but also throughout the platform’s operational lifespan. The inherent design translates to minimal maintenance requirements. Comprehensive insights into the construction and installation processes are provided in Campos, Molins, Gironella and Trubat [
34], considering the distinctive demands of the monolithic design. The authors conducted a comparative analysis of costs between steel and equivalent concrete platform designs and their findings underscore a material cost reduction exceeding 60% for the concrete design, reinforcing its economic viability.
Lerch et al., 2018 [
35], conducted a study exploring three platform concepts (spar, semi-submersible and TLP) for FOWTs, situated across different locations and comprising a 500 MW floating offshore wind farm. Their findings underscore the competitiveness of FOWTs, demonstrating their capacity to generate energy at an equivalent LCOE compared to fixed-bottom offshore wind technologies. They identified significant parameters influencing the LCOE of the FOWFs with potential for substantial cost reductions. Notably amongst these parameters are manufacturing-related costs, including those of the wind turbine, substructure and mooring system. These parameters are key factors driving LCOE variations across all concepts and offshore sites. They also highlighted how innovative ideas such as dedicated construction and assembly facilities tailored for floating wind can further contribute to cost reduction, particularly during the manufacturing phase of FOWF components.
Castro-Santos et al. [
36] developed a method to assess the economic viability of deep-water offshore wind farms by considering their economic factors. This procedure involves the use of various economic parameters, including internal rate of return, net present value and levelized cost of energy. Notably, the research indicated that among the considered platform types, the semisubmersible platform exhibited the most favorable levelized cost of energy (LCOE) value, followed by the spar platform and the TLP platform.
1.4. Optimization Review
Some innovative studies to improve the design and optimization of floaters also contribute to the process of maturing FOWT technology and making it as economically competitive as its fixed-bottom foundation counterpart. Some of the innovative technical and optimization studies are highlighted herein: -
Hall et al. [
37] focused on optimizing the hull shape and mooring lines of FOWTs across various substructure categories. This optimization was carried out using a Genetic Algorithm (GA) and a frequency domain model based on OpenFAST-3.3.0 software. Their model is a linear representation of hydrodynamic viscous damping and did not include a representation of wind turbine control. The GA was employed for both single and multi-objective optimization. The study’s outcomes revealed an unconventional design, highlighting the need for further refinement of cost functions in the optimization process.
Karimi et al. [
20] enhanced the research conducted by Hall et al. [
37] by implementing a new optimization algorithm and a linearized dynamic model, leading to improved optimal solutions. In their study, Karimi et al. [
20] introduced a fully coupled frequency domain dynamic model and a design parameterization approach. This allowed for the evaluation of system motions and forces in scenarios involving turbulent winds and irregular waves. Furthermore, they employed the Kriging–Bat optimization algorithm, a surrogate-based evolutionary approach, to facilitate the exploration and exploitation of optimal designs across three stability classes of platforms: MIT/NREL TLP, OC3-Hywind Spar and OC4-DeepCwind semi-submersible platforms. This optimization primarily aimed to assess the cost implications of platform stability, as reflected by the nacelle acceleration objective function, across these three categories of FOWT platform stability. This study shows an enhanced correlation between cost and substructure design compared to the previous work by Hall et al. [
37].
Hegseth et al. [
25] conducted a comprehensive design optimization for an integrated system including the platform, tower, mooring system and blade pitch controller for a 10 MW spar-type floating wind turbine. The study involved optimizing various design parameters for the spar, including its diameter and wall thickness along ten distinct sections. The hull of the spar is equipped with circumferential T-ring stiffeners, which reduced the required computational effort by ensuring the number of design variables is decreased by introducing B-splines with four control points for the ring stiffener parameters. The study’s findings revealed that the optimized platform exhibits a relatively small diameter within the wave zone and assumes an hourglass shape beneath the waterline. This particular design serves to minimize wave-induced loads on the structure. Additionally, the distinctive shape enhances the system’s restoring moment and natural frequency in pitch, resulting in an enhanced dynamic response within the low-frequency spectrum.
Dou et al. [
38] introduced an optimization framework tailored for the support structure of floating wind turbines, specifically the spar-buoy floater, which also includes the mooring system. This framework was developed from frequency domain modelling, and it extends its analytical capabilities to provide design sensitivities for various design criteria. This unique capability facilitates rapid optimization by leveraging on the Sequential Quadratic Programming (SQP) optimization algorithm.
The optimization techniques discussed in Hall et al. [
20], Hegseth et al. [
25], Hall et al. [
37] and Dou et al. [
38] also reviewed above have the capability of reducing the computational time for the design and analysis of FOWTs. The reduction in time to search a large design space and identify optimal solutions allows stakeholders to make informed decisions that can potentially help in driving down the cost of FOWTs to the levels of cost in fixed-bottom foundation turbines.
This study aims to further reduce computational time for design of bespoke FOWTs and also reduce the LCOE of a FOWF by integrating shape parameterization techniques using a B-spline parametric curve to model a spar. The design and analysis process of the spar is integrated with a gradient-free optimizer to search the design and analysis space and identify the optimal design within a minimal amount of design and analysis time.