Abstract Calcium carbonate scale formation is a significant challenge in oil production systems, particularly in intelligent completion valves, where complex flow and thermodynamic conditions can favor crystallization. Understanding and mitigating scale deposition in these components is crucial to ensuring long-term system integrity and efficiency. This study aims to map the risk of calcium carbonate scaling in intelligent completion valves by performing a sensitivity analysis of operational conditions, using a comprehensive multiphysics modeling framework. A numerical model integrating flow dynamics, thermodynamic equilibrium, and crystallization kinetics was developed. Flow characteristics within the valve geometry were evaluated using a dimensionless formulation to determine pressure, velocity, and volumetric flow distribution. A population balance model was employed to predict the mass of calcium carbonate deposition based on the fluid composition and operational conditions. Simulations considered a range of volumetric flow rates (2500 to 7500 barrels per day), temperatures (60 to 85 °C), and pressures (400 to 580 bar), using representative oil and water compositions from Brazilian reservoirs. The results revealed that higher flow rates, elevated temperatures, and lower pressures significantly increase the risk of carbonate scaling calcium. These conditions enhance supersaturation, thereby promoting nucleation and crystal growth. Deposition was predominantly observed in regions with high velocity and surface area, such as constrictions and trim locations within the valve. This study introduced a novel numerical approach that can guide the optimization and future control of operational parameters to mitigate scale formation in intelligent completion valves. A risk map was developed to evaluate scaling potential under various reservoir conditions, supporting more informed decision-making in flow control design and operation.
Dalla et al. (Tue,) studied this question.