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Slug flow

Slug flow is a prevalent regime in gas-liquid multiphase flow, characterized by the alternating passage of elongated liquid slugs—often containing dispersed gas bubbles—and large gas pockets, known as Taylor bubbles, that nearly occupy the full pipe cross-section.^[1]^[2] This intermittent pattern arises due to differences in phase densities and velocities, leading to hydrodynamic instabilities that promote the coalescence of liquid into slugs and the elongation of gas bubbles.^[3]^[4] In engineering contexts, particularly oil and gas production, slug flow commonly occurs in pipelines, wellbores, and risers transporting hydrocarbons, where it transitions from other regimes like bubbly or annular flow depending on factors such as superficial velocities, pipe inclination, and fluid properties.^[3]^[5] The liquid slugs can extend for tens to hundreds of pipe diameters, while Taylor bubbles propagate faster than the liquid, often reaching velocities 1.2 to 1.6 times the mixture velocity in vertical flows.^[3]^[6] Despite its ubiquity, slug flow poses significant challenges in industrial applications, including severe pressure and flow fluctuations that can overload downstream separators, induce pipeline vibrations and fatigue, accelerate corrosion and erosion, and even trigger automatic shutdowns of production platforms.^[5]^[7] These effects are exacerbated in offshore and deep-sea environments, where terrain-induced slugs accumulate liquids in low points before surging upstream.^[6]^[4] Mitigation strategies, such as slug catchers, active control via choke valves, or chemical inhibitors, are essential to manage these dynamics and ensure safe, efficient operations.^[8]^[3] Beyond petroleum engineering, slug flow influences processes in chemical reactors and heat exchangers, highlighting its broad relevance across disciplines.^[3] Research continues to refine predictive models for slug frequency, length, and pressure drops, with recent studies emphasizing advanced simulations and measurements to address gaps in turbulent and inclined flow conditions.^[9]^[10]

Fundamentals

Definition

Slug flow is an intermittent two-phase gas-liquid flow regime in pipes, characterized by the alternation of large gas bubbles—known as Taylor bubbles—that occupy most of the pipe cross-section, separated by liquid slugs containing dispersed gas bubbles.^[11] This pattern arises in multiphase systems where the gas and liquid phases do not maintain a uniform distribution, leading to successive plugs of each phase moving through the conduit.^[12] The regime was first investigated in the early 1940s through studies of large bubble dynamics in vertical tubes, with Dumitrescu providing pioneering theoretical analysis of bubble shape and motion in 1943.^[13] This work laid the foundation for understanding Taylor bubbles, later expanded upon by Davies and Taylor in 1950, who examined their rise through liquids in tubes. These early contributions emerged within broader multiphase flow research in the mid-20th century, focusing on the behavior of elongated gas pockets in liquid-filled conduits.^[14] Unlike other intermittent flows, slug flow exhibits a distinctly periodic nature, with repeating units of gas bubbles and liquid slugs that prevent steady-state uniformity along the pipe.^[11] This periodicity distinguishes it as a structured form of intermittency in gas-liquid systems.^[1]

Characteristics

Slug flow is distinguished by its alternating structural elements: elongated Taylor bubbles and intervening liquid slugs. Taylor bubbles are large gas pockets that occupy nearly the entire pipe cross-section, characterized by a rounded, bullet-shaped nose and a thin liquid film that falls along the pipe wall due to gravity and shear. These bubbles transport the majority of the gas phase and can extend over lengths much greater than the pipe diameter, with their shape and film thickness influenced by fluid properties and flow rates. Liquid slugs, in contrast, are regions dominated by the liquid phase, often containing small dispersed bubbles, and typically span 15 to 40 pipe diameters in horizontal configurations^[11], though lengths vary with superficial velocities and pipe inclination.^[15] The regime exhibits pronounced intermittency, arising from the differential velocities between phases, where Taylor bubbles advance faster than the surrounding liquid, creating periodic sequences of high and low liquid content. This results in alternating regions of elevated pressure during liquid slug passage and reduced pressure behind the advancing bubble front, producing characteristic fluctuations in pressure and liquid holdup at any fixed point along the pipe. Gas bubbles move at velocities approximately 1.2 to 1.5 times the mixture velocity in vertical flow, exacerbating the unsteady nature and leading to cyclic hydrodynamic behavior.^[16]^[15]^[17] Visually and experimentally, slug flow in horizontal pipes manifests as intermittent plugs of liquid separated by gas pockets, often evolving from stratified or wavy flow where interfacial waves grow, coalesce, and bridge the pipe to form slugs, with liquid holdup concentrated at the bottom due to stratification. In vertical pipes, the appearance shifts to symmetric, rising bullet-shaped bubbles enveloped by a falling annular liquid film, with liquid slugs fully occupying the cross-section; bubble coalescence within these slugs, driven by turbulence at the front interface, reforms the subsequent Taylor bubble. Liquid holdup in slugs is generally high (0.7–0.95), varying with gas fraction, and can be measured via conductivity probes or high-speed imaging to capture the intermittent passage.^[18] Pipe orientation significantly affects slug flow stability and structure: it is more stable in vertical upward flow, where buoyancy promotes consistent bubble rise and symmetric films, whereas downward flow tends toward instability and flooding when gas velocities are low relative to liquid, causing liquid accumulation and transition to churn or flooded regimes. In inclined pipes, increasing deviation from vertical enhances asymmetry in bubble shape and film distribution, with eccentricity rising as inclination decreases.^[11]

Occurrence and Transitions

Flow Regimes in Multiphase Flow

In gas-liquid two-phase flow through pipes, several major flow regimes are commonly observed, each characterized by distinct spatial distributions of the phases. Bubbly flow consists of small, dispersed gas bubbles within a continuous liquid phase, typically occurring at low gas fractions where bubbles remain spherical or ellipsoidal and follow the liquid motion. Slug flow features intermittent large gas bubbles, often called Taylor bubbles, that occupy nearly the full pipe cross-section and alternate with liquid slugs, creating a periodic structure. Churn flow represents a chaotic transitional regime with highly disturbed interfaces, where broken slugs lead to flooding-like waves and intense mixing of phases. Annular flow involves a central gas core surrounded by a thin liquid film along the pipe wall, with possible entrainment of liquid droplets into the core. Stratified flow, prevalent in horizontal pipes, exhibits gravitational separation with the gas phase flowing above a distinct liquid layer at the bottom.^[19] Slug flow occupies an intermediate position in the spectrum of regimes, bridging bubbly flow and more gas-continuous patterns like annular or churn flow; it dominates under conditions of moderate superficial gas velocities and low to moderate liquid velocities, where bubble coalescence leads to elongated gas pockets without full phase inversion. This intermittent nature of slug flow, with alternating gas and liquid sections, distinguishes it from the uniform dispersion in bubbly flow and the steady film in annular flow.^[20]^[19] The transition between these regimes is governed by key factors including the superficial velocities of the gas and liquid phases, which dictate the relative momentum and void fraction; pipe diameter, which affects bubble stability and coalescence rates; and fluid properties such as density, viscosity, and surface tension, influencing interfacial dynamics and phase separation. Pipe inclination also plays a role, with slug flow more prevalent in horizontal to slightly upward inclinations, where hydrodynamic instabilities promote slugging, while vertical flows favor churn or annular patterns at higher gas rates. A foundational classification tool for these regimes in horizontal pipes is the flow pattern map developed by Mandhane et al. (1974), which correlates observed patterns against superficial gas and liquid velocities using an extensive database of experimental observations.^[19]^[20]^[21]

Conditions for Slug Flow Formation

Slug flow forms in gas-liquid two-phase systems when the superficial gas velocity exceeds the bubble rise velocity, destabilizing the interface and promoting wave growth, but remains below the threshold for annular flow transition. This typically occurs at superficial liquid velocities of 0.01 to 0.5 m/s and superficial gas velocities of 0.1 to 3 m/s in horizontal or near-horizontal pipes, based on flow pattern maps like Mandhane et al. (1974).^[21] These velocity ranges allow intermittent alternation between liquid slugs and gas pockets, distinguishing slug flow from stable stratified or dispersed bubbly regimes. The regime is prevalent at average gas void fractions between 20% and 50%, where bubble coalescence dominates over breakup mechanisms, leading to elongated gas bubbles that bridge the pipe cross-section. At lower void fractions (around 20–30%), the transition from stratified wavy flow initiates slugging, while higher fractions up to 50% sustain the pattern before shifting to churn or annular flow. In this range, the average gas holdup supports the formation of coherent slugs without excessive entrainment.^[11] Key instability mechanisms drive slug initiation, including Rayleigh-Taylor instability at the liquid-gas interface, where denser liquid accelerates into lighter gas, causing perturbations to grow into waves that eventually form slugs.^[22] Kelvin-Helmholtz instability further amplifies these waves through shear between phases, accelerating interface deformation until liquid bridges the pipe.^[23] These hydrodynamic instabilities are most pronounced in low-viscosity systems, where surface tension moderates but does not suppress wave growth. Pipe geometry significantly influences slug formation; the regime is more common in laboratory-scale diameters of 2 to 10 cm, where wall effects promote bridging waves, while in larger industrial pipes (>10 cm), slug frequency decreases due to reduced capillary influences.^[24] Fluid properties also play a role; increasing liquid viscosity reduces slug frequency, while moderate surface tension in systems like water-air facilitates the pattern compared to high-tension fluids.^[24]

Hydrodynamic Modeling

Slug Velocity and Translational Velocity

In slug flow, the translational velocity U_T of the gas bubbles or slugs represents the speed at which the bubble front propagates relative to the pipe, and it is modeled using the drift-flux approach as U_T = C_0 U_m + U_d, where U_m is the mixture velocity (sum of superficial gas and liquid velocities), C_0 is the distribution parameter accounting for the non-uniform velocity profile (typically 1.2 for fully developed turbulent flow in vertical pipes), and U_d is the drift velocity due to buoyancy.^[25] For vertical upward flow, the drift velocity is often given by U_d = 0.35 \sqrt{g D}, where g is gravitational acceleration and D is the pipe diameter; this empirical relation arises from the balance between buoyancy and drag on elongated bubbles in low-viscosity liquids like air-water systems.^[26] This model captures how bubbles rise faster than the average liquid due to relative motion, with C_0 values ranging from 1.0 to 2.0 depending on flow regime and pipe orientation, higher for laminar conditions.^[27] The slug velocity U_s, which describes the propagation speed of the liquid slug body or the bubble nose, is closely related to the translational velocity and is approximately 1.2 to 1.3 times the average liquid velocity in the slug body for vertical flows, as derived from experimental observations of bubble rise in moving liquids.^[28] This relation, pioneered by Nicklin et al. in their analysis of two-phase flow in vertical tubes, stems from the bubble velocity equaling the maximum centerline liquid velocity ahead plus a drift component, with the factor 1.2 reflecting the velocity profile in turbulent pipe flow.^[28] In horizontal pipes, the translational velocity is given by U_T = 1.2 U_m + 0.54 \sqrt{g D}, accounting for the non-uniform velocity profile in the liquid slug and the stratified liquid layer at the pipe bottom, which influences the effective drift without forward buoyancy drive.^[29] For inclined pipes (angle \theta from horizontal), a combined correlation is used: U_d = 0.35 \sqrt{g D \sin \theta} + 0.54 \sqrt{g D \cos \theta}, blending buoyancy effects (dominant near vertical) with profile-driven drift (dominant near horizontal).^[30] Several factors influence these velocities, including pipe inclination, which reduces the effective gravitational component in the flow direction and thus lowers U_d relative to vertical flow, leading to slower slug propagation in near-horizontal setups compared to vertical ones. Fluid densities affect the buoyancy-driven drift, with higher density differences increasing U_d through enhanced relative motion between phases.^[31] The shape of the bubble nose also plays a role, as rounded or pointed noses experience less drag and achieve higher velocities, influenced by turbulence and surface tension in the preceding liquid slug.^[32] Experimental measurement of slug and translational velocities commonly employs high-speed imaging to visualize bubble passage and compute velocities from displacement over known distances, offering direct insight into nose dynamics and intermittency.^[33] Alternatively, pressure transducers mounted along the pipe detect abrupt changes during slug arrival and departure, enabling velocity calculation via cross-correlation of signals from multiple sensors spaced at fixed intervals.^[34] These non-intrusive techniques provide time-resolved data, essential for validating models under varying flow conditions.^[9]

Pressure Drop Calculations

In slug flow, the total pressure drop along a pipeline comprises three primary components: hydrostatic pressure drop due to elevation changes and fluid column weight, frictional pressure drop arising from wall shear in liquid slugs and surrounding films, and accelerational pressure drop resulting from momentum changes at gas-liquid interfaces during slug passage.^[35] These components are particularly pronounced in inclined or vertical pipes, where hydrostatic effects dominate, while horizontal configurations emphasize frictional and accelerational losses.^[10] The frictional pressure drop in slug flow is often estimated by adapting single-phase correlations to two-phase conditions using the Lockhart-Martinelli approach. The single-phase frictional gradient is given by

\frac{\Delta P_f}{L} = \frac{2 f \rho U^2}{D},

where f is the friction factor, \rho the fluid density, U the velocity, and D the pipe diameter. For two-phase flow, this is modified via the Martinelli parameter X = \sqrt{(\Delta P_L / \Delta P_G)}, where \Delta P_L and \Delta P_G represent single-phase frictional drops for liquid and gas flowing alone; the two-phase multiplier \phi_L^2 = 1 + C/X + 1/X^2 (with C \approx 20 for turbulent-turbulent flow) then yields the effective \Delta P_{TP} = \phi_L^2 \Delta P_L. Slug-specific adaptations for intermittent flow, such as the model by Gregory et al. (1978), incorporate holdup effects to refine predictions in horizontal gas-liquid systems.^[36] For a representative slug unit—comprising a liquid slug of length L_s followed by a gas bubble and film—the pressure drop is \Delta P_{\text{slug}} = \rho_L g L_s (1 - \alpha_s) + frictional terms, where \rho_L is liquid density, g gravitational acceleration, and \alpha_s the void fraction in the slug body (typically 0.2–0.4, reflecting dispersed gas bubbles).^[37] This hydrostatic term assumes vertical flow (\sin \theta = 1) and approximates mixture density as liquid-dominated; frictional contributions are added from slug and film regions using modified single-phase relations.^[38] Predicting pressure drop in slug flow presents challenges due to its unsteady, intermittent nature, necessitating unit cell models that average over multiple slugs for steady-state estimates.^[37] In horizontal pipes, correlations like Gregory et al. (1978) emphasize the gas-liquid density ratio indirectly through mixture velocity dependencies on holdup, improving accuracy for low-density gas systems but requiring validation against pipe diameter and fluid properties.^[36]

Applications

Oil and Gas Pipelines

Slug flow is prevalent in subsea and onshore pipelines transporting multiphase hydrocarbons, particularly in wet gas or oil-water-gas systems over long distances, where terrain undulations promote liquid accumulation and subsequent slug formation at low points. In the North Sea, for instance, the 13-km, 12-inch pipeline connecting the Hod field wellhead platform (operated by Aker BP) to the Valhall production platform has experienced terrain-induced slugging due to drops in oil production rates, leading to intermittent large liquid slugs. The Hod field underwent redevelopment in 2021–2025, with the new Hod B platform continuing multiphase transport via pipelines to Valhall, where similar slugging challenges persist.^[39]^[40] Similarly, large-diameter pipelines in the Prudhoe Bay field, Alaska, with diameters ranging from 12 to 24 inches over distances up to 3 miles, exhibit hydrodynamic slug growth as liquids travel downstream. The Troll field offshore Norway, featuring two 36-inch multiphase pipelines from a gravity base structure in 995 ft water depth, also encounters slugging influenced by production history and pipeline state. These slugs cause significant operational impacts, including fluctuating flow rates that compromise metering accuracy and separator performance. In the Hod field pipeline, slugging results in poor oil-water separation, reduced production capacity, excessive flaring, and frequent platform trips or shutdowns due to overloads on downstream facilities. At Troll Phase I, dynamic slug interactions between pipelines and the onshore plant necessitate rapid operator adjustments to gas export variations, potentially limiting overall system throughput and complicating process control. Severe slugging generally induces liquid surges that flood production separators and generate over-pressures, while gas blowouts following slug expulsion can inefficiently load compressors and increase wear on valves and piping. Design considerations for pipelines emphasize sizing to minimize severe slugging severity, often informed by transient multiphase flow simulations. For example, in the Troll field development, dynamic simulations assessed pipeline diameters and slugcatcher capacities to ensure feasibility under varying flow conditions, balancing capital costs with operational stability. Integration of tools like the OLGA dynamic multiphase flow simulator is standard for predicting slug behavior, enabling optimization of pipe inclination, diameter, and length to avoid excessive liquid holdup while supporting flow assurance during startup, shutdown, and rate changes. Historical incidents in the 1980s, stemming from unmanaged slugs in early North Sea developments, led to pipeline inefficiencies and prompted innovations in slug management. Severe slugging was first documented in offshore systems in 1973, but by the 1980s, growing multiphase transport in fields like those in the North Sea highlighted risks of production disruptions, driving the development of slug catchers—vessels designed to capture and separate liquid slugs at pipeline endpoints to prevent downstream flooding. This era saw numerous prediction models emerge, influencing modern designs to enhance reliability in long-distance hydrocarbon transport.

Chemical Engineering Processes

Slug flow finds significant application in chemical engineering processes, particularly within microreactors and monolith reactors, where it facilitates enhanced mass transfer through intermittent mixing induced by alternating gas and liquid segments. In microreactors, gas-liquid slug flow promotes internal circulation within liquid slugs, reducing diffusion paths and increasing the volumetric mass transfer coefficient; for instance, in CO₂ absorption processes using nanofluid systems, this results in up to a 2.6-fold enhancement compared to pure liquid single-phase flow. Similarly, in monolith reactors operating under Taylor flow—a form of slug flow—hydrogenation reactions such as the conversion of α-methylstyrene exhibit approximately a 3-fold increase in reaction rates relative to single-phase operations, attributed to improved gas-to-solid mass transfer via thin liquid films surrounding gas bubbles. These enhancements stem from the dynamic recirculation patterns that intermittently renew interfacial contacts, making slug flow ideal for gas-liquid reactions in compact reactor designs.^[41]^[42] In distillation and absorption columns, slug flow manifests as internal slugging within packed beds or monolith structures, improving operational efficiency by augmenting gas-liquid contact. This regime is particularly beneficial in monolith-based absorption systems, where the segmented flow ensures uniform wetting of catalytic surfaces and minimizes channeling, leading to higher absorption rates in processes like CO₂ capture with amine solutions. For example, in amine-promoted absorption columns using monoliths, slug flow enhances the removal efficiency of CO₂ from flue gases by promoting radial mixing and sustained interfacial renewal, outperforming traditional trickle-bed configurations in terms of mass transfer productivity. Such applications leverage the inherent low pressure drop of slug flow to maintain high throughput in vertical column operations.^[43] Key advantages of slug flow in these processes include its provision of high interfacial areas and effective radial mixing with minimal axial dispersion, enabling precise control in reactive separations. Interfacial areas in slug flow microreactors and monoliths can reach up to 3476 m²/m³ due to the thin films and bubble caps, facilitating rapid mass transfer without the need for mechanical agitation. In pharmaceutical synthesis, case studies demonstrate these benefits; for instance, the biphasic epoxidation of methyl oleate in capillary reactors achieves over 95% conversion with tunable selectivity through slug length adjustments, yielding volumetric mass transfer coefficients of 0.88–1.67 s⁻¹ and highlighting its utility in fine chemical production. Another example is the enzymatic synthesis of L-phenylserine in slug-flow microchips, where the regime supports high-yield reactions by stabilizing immiscible phases and enhancing enzyme-substrate interactions.^[43]^[44] Despite these merits, scale-up of slug flow from laboratory (mm-scale channels) to pilot (cm-scale) systems presents challenges in maintaining slug stability and uniformity. As channel dimensions increase, perturbations in flow rates or fluid properties can disrupt the alternating slug-bubble pattern, leading to transitions to less efficient regimes like annular flow and causing fouling from uneven deposition. Studies on precipitation processes show that while slug flow can be scaled by increasing slug numbers and cycle times—achieving uniform microcrystals across 10-fold volume increases—stability requires careful control of residence times and cleaning protocols to prevent wall adhesion, with productive operation limited to about 82% of total time in pilot setups. Multidisciplinary strategies, including hydrodynamic modeling and material selection, are essential to mitigate these issues during translation to larger pipes.^[45]^[46]

Challenges and Mitigation

Induced Vibrations and Erosion

Slug flow generates significant flow-induced vibrations (FIV) in pipelines primarily through intermittent impact loading from alternating liquid slugs and gas pockets, which exert dynamic forces on pipe walls and components such as elbows due to momentum changes. These forces arise from the sudden deceleration and redirection of the slug mass, modeled as F = \rho_s A V_{se}^2, where \rho_s is the slug density (typically 1000 kg/m³ for water-based slugs), A is the pipe cross-sectional area, and V_{se} is the slug exit velocity at bends, ranging from 15 to 58 m/s depending on driving pressure and pipe geometry.^[47] Such impacts can lead to cyclic stresses that excite pipe vibrations at low frequencies, generally a few Hz, with pressure fluctuations below 1 Hz and slug collision forces above 1 Hz; resonance occurs when these frequencies align with the pipe's natural modes, amplifying displacements and potentially causing structural fatigue.^[48] Erosion in slug flow results from the high-velocity impingement of liquid slug fronts on pipe interiors, accelerating material removal through turbulent shear and particle bombardment, particularly in carbon steel pipelines. Under multiphase conditions with CO₂-saturated environments, wall thinning rates can reach up to 2.0 mm/year at liquid velocities of 0.55 m/s, with rates increasing due to enhanced turbulence from higher slug frequencies (e.g., up to 80 slugs/min).^[49] Sand entrainment in the flow further intensifies erosion-corrosion, as abrasive particles in the slugs heighten localized damage at bends and low points, where velocities and impacts are maximized.^[49] Vibrations and erosion risks are assessed using instrumentation such as strain gauges for stress monitoring and accelerometers for displacement and frequency analysis, revealing patterns tied to slug passage that inform fatigue life predictions.^[50] Case studies, such as the 20-inch submarine pipeline in China's Lingshui 25-1 gas field, demonstrate how slug-induced cyclic loading can lead to fatigue failures, with damage varying significantly based on slug length, velocity, frequency, and density, often necessitating optimized designs to mitigate accumulated stress over operational lifespans.^[51] Exacerbating factors include pipeline configurations with bends, undulations, or risers, where severe slugging—characterized by prolonged liquid accumulation and rapid expulsion—amplifies dynamic loads through heightened pressure and momentum fluctuations.^[52] In such systems, particularly flexible lazy wave risers during moderate production phases, slug flow can elevate the standard deviation of bending curvature and increase fatigue damage by factors of 100 to 1000 compared to steady flow, underscoring the need for detailed fluid-structure interaction modeling to quantify these effects.^[52]

Flow Control Strategies

Flow control strategies for slug flow primarily aim to suppress intermittent flow patterns, stabilize multiphase transport, and prevent operational disruptions in pipelines and process systems. These approaches encompass chemical, hardware, operational, and modeling-based techniques, each tailored to specific flow conditions and system geometries. By altering fluid properties, accommodating liquid accumulation, or dynamically adjusting operating parameters, these methods enhance flow stability and efficiency. Chemical methods involve the injection of additives such as surfactants or drag-reducing polymers to modify interfacial tension, reduce turbulence, and dampen slug formation. Surfactants like sodium dodecyl sulfate (SDS) at concentrations around 400 ppm have been shown to reduce drag in air-water slug flows in horizontal pipes by promoting smoother liquid films and minimizing wave formation that leads to slugging.^[53] Similarly, drag-reducing polymers (DRPs), typically added at 0.1-0.5 wt%, can decrease frictional pressure drops in slug-dominated gas-liquid flows by up to 40%, while also lowering slug frequency under certain gas and liquid velocities by suppressing liquid holdup and bubble coalescence.^[54]^[55] These additives stabilize the flow toward stratified or annular regimes, particularly effective in long horizontal pipelines where slug initiation is prevalent. Hardware solutions provide physical means to handle and absorb large liquid slugs without overwhelming downstream equipment. Slug catchers, installed at pipeline endpoints, temporarily store incoming liquid volumes to allow controlled separation of gas and liquid phases. Vessel-type slug catchers function as large separators with capacities suitable for volumes under 100 m³, offering simple design for moderate slug sizes, while finger-type (multiple-pipe) designs accommodate larger accumulations up to 1000 m³ or more through parallel pipe fingers that provide extended holdup volume.^[56]^[57] Additionally, gas lift systems or recirculation pumps inject gas at strategic points, such as the riser base, to increase superficial gas velocity and break up liquid slugs, thereby shifting the flow regime and reducing accumulation. These devices are commonly deployed in offshore subsea tiebacks to manage terrain-induced slugs. Operational controls rely on real-time adjustments to flow parameters to avoid slug-prone conditions. Choking valves at the topside or riser outlet restrict flow to increase backpressure, suppressing severe slugging by maintaining velocities above critical thresholds for annular flow transition; however, this must be balanced to avoid excessive production losses.^[58] Active feedback systems integrate pressure and flow sensors with automated controllers to throttle valves dynamically—for instance, opening the valve during low-flow periods to boost throughput or closing it to stabilize pressure cycles—effectively eliminating oscillatory slug behavior in pipeline-riser setups. Such strategies are widely applied in offshore platforms, where they maintain steady production without hardware modifications. Advanced modeling integration employs computational tools for predictive control, simulating transient slug dynamics to inform proactive interventions. Computational fluid dynamics (CFD) models capture slug initiation, propagation, and mitigation in complex geometries, enabling optimization of valve settings or additive dosages to prevent regime shifts.^[59] Transient multiphase simulators like OLGA or PIPESIM predict slug volumes and frequencies in offshore networks, allowing operators to adjust rates preemptively; for example, integrations in subsea systems have demonstrated improved flow assurance by forecasting and averting slug-induced shutdowns.^[60]^[61] These tools support scenario-based planning, prioritizing high-impact adjustments over reactive measures.

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This study aims to investigate air–water slug flow along a horizontal transparent pipe with a diameter of 0.074 m by using a non-intrusive image processing ...
[37]
[PDF] Slug Velocity Measurement and Flow Regime Recognition Using ...
Many commercially available techniques are used to detect and measure the slug characteristics in two phase flow including ultrasonic methods, conductivity.
[38]
Full article: Stability analysis of slug flow control
In this paper, a new general method for multiphase flow system stability analysis was proposed. Active feedback control was observed to optimize slug ...
[39]
Correlation of the liquid volume fraction in the slug for horizontal gas ...
The results of this investigation are important for the development of a mechanistic model for the prediction of pressure drop and holdup for slug flow in pipes ...
[40]
Mechanistic modeling of flow and heat transfer in vertical upward ...
Jan 12, 2022 · The frictional pressure drop of the total slug unit cell, Δ P F ⁠, is composed of the pressure drop associated with the liquid slug, ...
[41]
Experimental study of the hydrodynamic behaviour of slug flow in a ...
This paper presents an investigation of the hydrodynamics of slug flow in a vertical 67 mm internal diameter riser. The slug flow regime was generated using ...Missing: sqrt( | Show results with:sqrt(
[42]
Gas–Liquid Slug Flow Studies in Microreactors: Effect of ... - Frontiers
Jan 16, 2022 · The gas-nanofluid slug flow was utilized to enhance the mass transfer of CO2 absorption in a square microchannel, where the liquid side ...
[43]
[PDF] Reaction Rate Enhancement of Three-Phase Hydrogenation Using ...
A gas–liquid–solid three-phase reaction was conducted in a Taylor flow reactor to improve the apparent reaction rate by enhancing the mass transfer rate of the ...
[44]
[PDF] Monoliths as Multiphase Reactors: A Review - Scholars' Mine
Nov 1, 2004 · A short diffusion length can be obtained by operating the monolith in two-phase slug flow (Taylor flow) or in the annular flow regime. Taylor ...
[45]
Slug flow as tool for selectivity control in the homogeneously ...
Oct 5, 2021 · The improved mass transfer and reduced back mixing of the biphasic liquid–liquid slug flow allows for selectivity control depending on physical ...
[46]
Direct Precipitation Pathway to Pure α-MnC2O4·2H2O Using Slug Flow toward the Scalable Nonfouling Fast Synthesis of Uniform Microcrystals
### Scale-Up Challenges and Stability Issues for Slug Flow
[47]
Overcoming the Hurdles and Challenges Associated with ...
Oct 1, 2020 · This Minireview article aims to highlight some of the pitfalls associated with the development of a continuous process, focussing on translating the process ...
[48]
[PDF] Dynamic Force on an Elbow Caused by a Traveling Liquid Slug
Feb 27, 2014 · The impact force on an elbow induced by traveling isolated liquid slugs in a horizontal pipeline is studied. A literature review reveals ...Missing: kN | Show results with:kN
[49]
Experimental investigation on the vibration characteristics induced ...
The frequency of passing slug flow is usually about few Hz, so the slug flow-induced vibration is expected to occur in the relatively low-frequency range.
[50]
Carbon-steel corrosion in multiphase slug flow and CO2
Carbon-steel corrosion is enhanced by slug flow turbulence and CO2 presence in hydrocarbons, with corrosion rates varying with flow turbulence.
[51]
Vibration Analysis of a Pipe Conveying Two-Phase Flow ... - OnePetro
Jun 16, 2024 · Pipelines frequently experience vibration due to fluid-induced forces, presenting a complex array of destabilization mechanisms and dynamic ...
[52]
Slugging Flow Induced Fatigue Analysis for Submarine Pipeline
Jun 16, 2024 · Slugging flow is a nonlinear, unstable and periodic transient behavior, which may cause fatigue damage or even fatigue failure of pipelines.
[53]
A study on effects of slug flow on dynamic response and fatigue ...
Dec 1, 2020 · In case of compliant type risers, slug flow may cause substantial dynamic load effects. Slug flow (a series of liquid slug separated by a ...
[54]
Review on Methods of Drag Reduction for Two-Phase Horizontal ...
Wilkens and Thomas [29] used SDS as a surfactant to achieve DR in air-water slug flow through horizontal pipe. 400 ppm of SDS added in water reduced the ...
[55]
Experimental study of drag reduction by a polymeric additive in slug ...
The present study involves the drag reduction by a DRA in slug flow regime of air and oil in smooth and rough pipes. Slug flow is selected for two reasons: ...
[56]
Effects of Drag-Reducing Polymers on Stratified and Slug Gas ...
Jan 11, 2013 · This paper presents experiments in which the effect of drag-reducing polymers (DRP) on the frictional pressure drop of stratified flow and ...
[57]
[PDF] Masterarbeit
The vessel type slug catcher is basically a conventional vessel, simple in design and maintenance. It is preferably installed when liquid volume < 100 m3 has to.
[58]
5 Project Metrics to Assess if you Need a Finger or Vessel Slug ...
Storage Capacity or Size of your Slug. 1500 bbls or less: Vertical L-Type ... A standard vessel slug catcher (say 500 bbls) is 30-42 weeks. A custom ...Missing: 100-1000 m3
[59]
Slug flow control using topside measurements: A review
Mar 15, 2022 · Subsea pipelines and risers transfer multiphase fluids from offshore oil wells to topside facilities. Slugging flow patterns occur in pipeline- ...Missing: prevalence | Show results with:prevalence
[60]
Computational fluid dynamic (CFD) modelling of transient flow in the ...
The current study shows that computational modeling is a proven simulation program for predicting intermittent gas lift characteristics and the transient flow ...Missing: PIPESIM | Show results with:PIPESIM
[61]
Olga dynamic multiphase flow simulator - SLB
Oct 18, 2023 · The Olga dynamic multiphase flow simulator models transient flow (time-dependent behaviors) to maximize production potential.
[62]
[PDF] PIPESIM 2019 - Steady-State Multiphase Flow Simulator
PIPESIM is a leading steady-state multiphase flow simulator for production system design, providing advanced modeling capabilities and calculating flow regimes.