Within refinery digital twin and tank farm simulation models, this representation is used to capture key operational mechanisms product flow accumulation, discharge processes, capacity limitations, and state transitions. These mechanisms are typically evaluated through
flow statistics, storage utilization, and tank utilization metrics. Unlike static storage assumptions, modern simulation frameworks such as AnyLogic-based
Petroleum Refining Library models treat tanks as dynamic objects that continuously update their state based on inflow/outflow conditions, production planning rules, and pipeline or loading constraints. Production planning rules are typically implemented using
request-based production planning. Available storage capacity can also be increased through
dynamic tank reallocation.
This modeling approach enables accurate representation of refinery logistics systems, supporting tasks such as production planning, feedstock balancing, and
supply chain optimization. As a result, tank representation becomes a foundational element in oil and gas digital twin architectures, ensuring that storage behavior is consistently aligned with real operational dynamics and decision-making processes.
Tank farms are a key element of refinery logistics, providing a buffer between production, transportation, and processing units. They stabilize system operations by decoupling continuous refinery processes from discrete supply and shipment activities, reducing the impact of flow fluctuations and scheduling mismatches. Tank farms are a core layer in refinery simulation systems, acting as dynamic buffers between different elements such as production units, pipeline networks, storage systems and others.
In refinery imitation modeling, a tank is not just a storage vessel but a dynamic object that regulates balance across the supply chain. It tracks residual levels, manages inflow and outflow, and enforces constraints such as capacity limits, maximum and minimum volumes. During simulation, these parameters are continuously monitored using
storage statistics and
individual tank statistics. Maintenance outages can be represented using
tank repair simulation. This makes tanks essential components in refinery simulation and digital twin systems.
In simulation models, tank farms are usually represented in
two main configurations: flowing tanks, which handle continuous inflow/outflow dynamics, and
accumulative tanks, which are more tightly linked to production plans and shipment scheduling. This distinction allows accurate modeling of both operational behavior and planning-level constraints in refinery systems. The operational differences between flowing and accumulative tank farms become evident when comparing their
performance metrics, storage utilization, and operational statistics during simulation.