Hydraulic turbines are increasingly used for power grid regulation as intermittent energy resources, such as wind and solar power, gain prominence. The power output from these renewable sources fluctuates over short and long periods depending on weather conditions. Therefore, hydraulic turbines often operate away from their design point to mitigate grid imbalances, such as low-load operation, which presents challenges. The guide vanes control the flow, and their opening angle is limited during low-load conditions to restrict the flow rate and reduce power output, creating a high swirl flow condition. During part load (PL) operation, the residual swirl entering the draft tube can initiate a rotating-vortex-rope (RVR) that wraps around a stagnant region, introducing severe pressure pulsations. Some turbines are expected to provide a spinning reserve, enabling rapid responses to grid power shortages. One method to achieve a spinning reserve is to allow the turbine to operate under speed-no-load (SNL) conditions, where the turbine rotates at synchronous speed without generating electrical power. Since the turbine does not extract any power, the energy must be dissipated through the flow field. The resulting chaotic flow field features sometimes rotating vortices attached to the head cover in the vaneless space, extending into the draft tube. The axial flow primarily occurs in a thin region near the outer wall, while a recirculating region exists at the center of the draft tube, potentially extending upstream of the runner. Similar to the RVR, the rotating vortices induce harmful pressure pulsations throughout the turbine, jeopardizing safe operation and shortening the turbine's lifespan due to an increased risk of material fatigue.

This thesis aims to study the flow under low-load operating conditions for a Kaplan model turbine, specifically the Porjus U9 model, using computational fluid dynamics (CFD), and to explore a mitigation strategy that reduces pressure pulsations during these low-load operating conditions. The idea is to limit swirl and, consequently, the pressure pulsations caused by the flow structures by employing asynchronous guide vanes. This involves adjusting some guide vanes to a larger opening angle, while keeping the others closed and maintaining the same power output. Unlike other mitigation techniques, no additional installations are needed aside from an option to control some of the guide vanes asynchronously. CFD is combined with machine learning to explore various guide vane configurations efficiently.

Results indicate that vortices in the vaneless space during SNL operation can be mitigated, significantly reducing the associated pressure pulsations by opening one consecutive section of guide vanes. However, the jet like flow from the opened guide vane section generates a significant radial force on the runner due to the asymmetric flow field and pressure pulsations on the runner blades, oscillating at the runner's rotational frequency. Both issues can be addressed by opening two sections of guide vanes on opposite sides of the runner axis while maintaining most of the mitigation effect. Furthermore, the flow field is predictable, and most stochastic pressure pulsations are reduced, positively impacting the turbine's lifespan. One section with open guide vanes during PL operation can decrease the amplitude of the pressure pulsations related to the RVR rotating mode (RM) and plunging mode (PM) in the draft tube. Conversely, the stochastic pressure variations increase, and the runner is subjected to an asymmetric radial force and pressure pulsations on the blades that oscillate at the runner's rotational frequency, much like for SNL operation. Additionally, efficiency decreases, and the torque on the runnervaries more. The mitigation effect diminishes when opening two guide vane sections, as the RVR reduces in size, but is not completely mitigated.

The asynchronous guide vanes primarily affect the flow upstream of the runner, making the technique suitable for SNL operation, as the vortices originate upstream of the runner. The mitigation strategy is less effective during PL because the RVR originates in the draft tube. While the pressure pulsations related to the RVR can be reduced, significant stochastic variations persist. Furthermore, since the flow rate is higher during PL than SNL, the runner is subjected to higher-amplitude pressure pulsations and a more excessive radial force. Ultimately, implementing asynchronous guide vanes balances increased life expectancy and the cost of turbine operation. Experimental investigations are necessary to validate the above findings and clarify the actual effect on material fatigue and other parts of the turbine not included in the simulations.

The global construction sector has witnessed exponential growth in concrete utilization over the past seven decades, with annual consumption over 9.42 billion m³ in 2021. This surge, driven by rapid urbanization, has positioned concrete as the dominant construction material while creating critical environmental burden. In response to these challenges, the Swedish concrete industry has committed to making all concrete climate-neutral by 2045, with market-ready climate-neutral concrete available by 2030. To reduce the negative environmental impact of the concrete, transitioning from linear to circular economic models presents a viable approach, particularly through integrating wastes and industrial by-products (e.g., fly ash, slag) as supplementary cementitious materials (SCM) into concrete formulations. However, this ecofriendly construction practice faces severe challenges at establishing and executing SCM concrete configurations (including concrete mixes and site construction methods). During plan establishment, the systemic environmental and economic impacts of SCM concrete—spanning cradle-to-practicalcompletion phases—remain insufficiently examined. The complex interactions between SCM concrete’s mechanical properties (e.g., prolonged hydration and decreased early strength) and site construction methods (e.g., formwork duration, occupancy of labour and equipment) increase the difficulty in quantification. For example, while SCM concrete reduces embodied carbon in production, its delayed strength gain may necessitate prolonged formwork use or require energy-intensive methods (e.g., thermal treatment) to meet project timelines. To mitigate this, engineers might opt for a higher concrete grade to accelerate early strength development—though this risks offsetting sustainability gains of SCM concrete. Such adaptations often erode projected emission reductions and inflate costs, shifting burdens across stages. These cross-stage trade-offs underscore the need for integrated, cradle-to-practical-completion evaluations of the environmental and economic impacts of SCM concrete to avoid suboptimal overall performance. Furthermore, optimising SCM concrete configurations based on quantified performance metrics presents a significant computational challenge. This is due to the exponentially growing solution space resulting from the numerous combinations of SCM concrete mix designs and site-specific construction methods. As a result, exhaustive exploration of the solution space becomes computationally intensive, often leading to incomplete identification of optimal trade-offs between environmental benefits (e.g., reduced GHG emissions) and economic constraints (e.g., labour costs, construction time). Even after obtaining optimal SCM concrete configurations, real-world variability—such as fluctuating temperatures affecting curing rates —introduces uncertainty into project outcomes during site execution. For example, warmer weather than predicted will make former planed thermal curing measures become overprotection, leading to unnecessary expenses and energy consumption. To address this, robust optimisation frameworks are needed to simultaneously account for cross-stage interdependencies and operational uncertainties. Despite the critical need for integrated solutions, existing research on SCM concrete construction has largely remained discipline-specific—a divide rooted in the fragmented nature of the construction industry and its supply chain. Studies on SCM material properties are primarily limited to construction materials research, while on-site optimisation is explored within construction management. This fragmentation has prevented the integration of these two critical dimensions into a unified framework, limiting a comprehensive understanding of their collective impacts on a project’s economic and environmental performance. Based on gaps in previous studies, three research questions are formulated: RQ1: What systemic interdependencies exist between SCM concrete’s mechanical properties and site construction methods, and how do these interactions influence the cradle-to-practical-completion performance of SCM concrete? RQ2: What critical trade-offs arise when optimizing SCM concrete configurations across environmental benefits and economic constraints, and how can these trade-offs be systematically prioritized to avoid sub-optimisation? RQ3: What influence do weather-induced uncertainties have on the trade-offs between environmental benefits and economic constraints of SCM concrete construction practice across cradle to practical completion, and how should site construction methods be dynamically adapted to optimize these objectives under variable conditions? To address the formulated research questions, the research underlying this thesis was conducted in three following procedures: (1) Problem identification, which investigated both the operational demands of SCM concrete construction practice and existing theoretical limitations hindering the realization of full ecofriendly potentials of SCM concrete; (2) Method development, which constructed a holistic approach to overcome the identified theoretical gaps; (3) Method validation, which built three according prototypes as practical solutions to the identified problems and applied them to actual construction case projects to examine the effectiveness of the proposed methods. Each research question is addressed by a purpose-built model tailored to the specific technical and decision-making challenges associated with the use of SCM concrete. These models offer targeted solutions across life cycle analysis, optimisation, and uncertainty management: CSCD (Collection–Simulation–Calculation–Decision) for RQ1: This model integrates Discrete Event Simulation (DES), environmental impact assessment, and concrete maturity analysis to evaluate the environmental and economic performance of SCM concrete across the cradle-to-practical-completion span. It explicitly captures the interdependencies between SCM concrete’s mechanical properties (e.g., strength development) and construction practices (e.g., formwork duration), supporting holistic performance quantification. ESO (Ensemble learning–Simulation–Optimisation) for RQ2: This model combines ensemble machine learning techniques with simulation-based optimisation to efficiently navigate the expanded solution space of SCM concrete mixes and site construction methods. It enables comprehensive multiobjective trade-off analysis between environmental benefits (e.g., GHG emissions reduction) and economic constraints (e.g., cost, time), while minimising computational demand and the risk of sub-optimal outcomes. MADS (Modelling–Automation–Decision Support) for RQ3: This model integrates dynamic weather data, concrete maturity modelling, and automated decision rules to support the dynamic adaptation of construction practices—such as curing duration and protection measures—in response to temperature fluctuations. It enhances the reliability and responsiveness of SCM concrete implementation under weather-related uncertainties.

This research directly supports the strategic goals of the Swedish roadmap for climate-neutral concrete through a systematic and holistic approach to the use of SCMs. The roadmap emphasizes several key strategies, including: optimising the composition of concrete, replacing parts of the cement with alternative binders; contributing towards ensuring that the right concrete is used in the right place, i.e. avoiding higher concrete quality than necessary for the bearing capacity and durability of the building. The proposed research approach contributes to each of these areas in the following ways: (1) Optimizing Concrete Composition. In alignment with the roadmap’s focus on reducing cement content, this research provides a structured method for evaluating and selecting SCMs as partial cement replacements. The CSCD model, developed in response to RQ1, enables a comprehensive environmental and economic assessment of different SCM concrete mixes, considering their mechanical behavior and performance during construction. (2) Ensuring the Right Concrete is Used in the Right Place. Overdesign of concrete—using unnecessarily high-grade concrete mixes—leads to avoidable emissions and costs. The research supports decision-makers in selecting concrete grades that match structural needs without overdesign. The CSCD model quantifies performance relative to functional demand, minimizing unnecessary environmental burdens and ensuring practical suitability on-site. (3) Lifecycle-Based Environmental and Economic Assessment. Avoiding impact shifting across project stages requires integrated evaluation from material selection to project delivery. This research embeds a cradle-to-practicalcompletion perspective throughout all phases of assessment. While the CSCD model forms the backbone of this life cycle analysis (per RQ1), the ESO and MADS models (developed under RQ2 and RQ3) extend this thinking into planning and execution, capturing downstream impacts and variability. (4) Multi-Objective Optimization for SCM Usage Planning. Identifying optimal SCM configurations under multiple, often conflicting objectives—such as reducing emissions while controlling costs and timelines—is critical. This research introduces the ESO model, developed for RQ2, which combines simulation with ensemble learning to explore a vast solution space efficiently. It reveals optimal trade-offs while managing computational complexity. (5) Managing Construction Uncertainties and Climate Variability. Realworld variability, especially weather-induced fluctuations, can disrupt curing rates and lead to mismatches between planned and actual outcomes. To address this, the MADS model, developed for RQ3, enables dynamic adaptation of construction measures such as curing protocols. It enhances the reliability and environmental performance of SCM concrete application under uncertain site conditions.