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Azimuth thruster

An azimuth thruster is a marine propulsion device featuring a propeller housed in a rotatable pod or gondola that can swivel 360 degrees around a vertical axis, enabling omnidirectional thrust without relying on separate rudders or steering mechanisms.^[1]^[2] This design integrates propulsion and steering into a single unit, typically driven by mechanical or electrical systems, and is mounted either underwater in the hull or as a retractable bow thruster.^[3]^[4] The origins of azimuth thrusters trace back to 19th-century innovations in steerable propellers, with early concepts like the "propelling rudder" patented by Francis Ronalds in 1859.^[4] However, the modern form emerged in the mid-20th century, when Joseph Becker, founder of Schottel, invented the Z-drive transmission in 1950, allowing efficient power transfer through a Z-shaped shaft arrangement for horizontal rotation.^[2]^[4] Advancements continued with electrical podded designs, such as ABB's Azipod introduced in the late 1980s, where the electric motor is housed directly in the underwater pod for simplified installation and reduced mechanical complexity.^[4]^[1] Azimuth thrusters are classified into mechanical types like Z-drives (with horizontal input and Z-shaped gearing) and L-drives (vertical motor to horizontal output), as well as electrical variants including pusher (propeller behind the pod) and tractor (propeller ahead) configurations.^[2]^[1] They offer key advantages such as superior low-speed efficiency, precise dynamic positioning, reduced noise (especially in tractor units, up to 20 dB lower), and halved crash-stop distances compared to conventional systems, though they can be vulnerable to damage in shallow waters or grounding.^[1]^[3] Widely applied in cruise ships, ferries, icebreakers, offshore supply vessels, and naval craft, these thrusters have become standard for new constructions requiring high maneuverability, with power ratings ranging from 185 kW to over 8 MW.^[2]^[4]^[3]

Fundamentals

Definition and Purpose

An azimuth thruster is a steerable marine propulsion device consisting of a propeller housed in a rotatable pod or gondola, mounted externally below the hull, that enables 360-degree horizontal rotation to direct thrust in any desired direction without requiring a separate rudder.^[5] This configuration integrates propulsion and steering into a single unit, allowing vessels to achieve omnidirectional movement efficiently.^[1] The primary purpose of azimuth thrusters is to significantly improve vessel maneuverability, especially at low speeds, during docking and berthing operations, and for maintaining precise dynamic positioning in challenging conditions such as offshore oil platforms.^[4] By eliminating the need for traditional rudders and associated mechanical linkages, these thrusters reduce hydrodynamic drag and fuel consumption, enhancing overall operational efficiency and simplifying vessel design.^[6] Emerging as a mid-20th-century innovation, azimuth thrusters provided a practical alternative to fixed propeller and rudder systems.^[7]

Basic Principles

The physics of thrust in an azimuth thruster relies on Newton's third law of motion, which states that for every action, there is an equal and opposite reaction. The propeller accelerates water backward, generating a forward thrust force on the vessel as the reaction to the change in water momentum. This propulsive force vector can be directed in any horizontal orientation, while torque for rotating the thruster unit is provided through the azimuth bearing, enabling precise alignment without additional rudders.^[8] Rotational mechanics allow the azimuth thruster to swivel 360 degrees around a vertical axis, aligning the thrust axis with the required direction for propulsion or maneuvering. This is achieved using hydraulic or electric drives that actuate the rotation, typically responding at rates of 10-12 degrees per second to support dynamic positioning. The drive system transmits torque to the bearing, ensuring smooth reorientation of the propeller pod relative to water flow.^[8]^[9] Efficiency in thrust modulation depends on the propeller blade configuration and its interaction with incoming water flow. Fixed-pitch blades provide high efficiency at the design speed but require variable rotational speed for thrust adjustment, achieving lower thrust in reverse due to flow reversal limitations. Variable-pitch blades, in contrast, allow direct angle adjustment to optimize thrust across speeds, though they may consume additional power at idle unless RPM is reduced, enhancing overall hydrodynamic efficiency by matching blade pitch to flow velocity.^[8] The direction of the resultant thrust \vec{T} is resolved as a vector based on the azimuth angle \theta, given by

\vec{T} = T \left( \cos\theta \, \hat{i} + \sin\theta \, \hat{j} \right),

where T is the thrust magnitude, \hat{i} and \hat{j} are unit vectors in the surge (x) and sway (y) directions, respectively. This formulation enables omnidirectional control by varying \theta through the rotational drive.^[10]

Design and Components

Core Structural Elements

The core structural elements of an azimuth thruster form the foundational framework that supports its rotational capability and integration with the vessel's hull, ensuring durability in harsh marine conditions. These elements primarily include the pod housing, mounting interfaces, and azimuth bearing, all designed to withstand hydrodynamic forces and corrosion while facilitating 360-degree maneuverability.^[11] For underwater-mounted units, the pod housing is a streamlined, axisymmetric enclosure that contains the drive system and propeller, typically suspended below the hull by an aerofoil-shaped fin to minimize drag. This housing protects internal components from seawater exposure and contributes to the thruster's hydrodynamic efficiency.^[11] The mounting system employs a skirt or well structure to secure the thruster to the vessel, with the well providing a recessed installation point that allows for protected integration into the hull. These mounting interfaces distribute loads from thrust and rotation, often bolted to a hull flange for stability.^[12] The azimuth bearing, commonly a ball or roller type such as radial or spherical roller bearings, enables smooth 360-degree rotation of the pod relative to the fixed upper structure, supporting the vertical shaft and gearbox while handling axial and radial loads. These bearings are positioned at key junctions, including swing-up connections to the hull, to ensure reliable steering without excessive friction.^[12]^[13] Materials for these structural elements prioritize corrosion resistance, utilizing alloys such as bronze, stainless steel, or nickel-aluminum bronze for the pod housing and bearing components to combat marine corrosion and cavitation. Seals, including mechanical and lip types, are integrated to prevent water ingress into the bearing and gearbox areas, maintaining lubrication and structural integrity over extended service periods.^[11]^[14] Installation types vary between through-hull configurations, such as the Z-drive where the unit penetrates the hull bottom for direct engine connection, and deck-mounted L-drive setups that position the thruster above the waterline for easier access. Well-mounted variants, using a protective well or skirt, are common for tugs and ferries to enhance installation flexibility without dry-docking.^[12]^[15]^[16] Size scaling of these elements is tailored to vessel displacement, with power ratings typically ranging from 100 kW for small craft to 5,000 kW or higher for larger ships, influencing the dimensions of the pod, bearing diameter, and mounting strength to match operational demands.^[15]^[12] Safety features integral to structural design include overload protection through robust bearing capacities that prevent failure under excessive thrust, and vibration dampening elements such as flexible mounts or fin suspensions to reduce hull transmission and enhance longevity. Advanced sealing systems also incorporate leak detection to safeguard against ingress-related hazards.^[11]^[17]

Propulsion and Steering Mechanisms

Azimuth thrusters generate propulsion through propellers mounted within a rotatable pod, utilizing either fixed-pitch propellers (FPP) or controllable-pitch propellers (CPP). FPP designs maintain a constant blade angle, providing reliable thrust in a straightforward configuration suitable for steady operations, while CPP systems allow dynamic pitch adjustment via hydraulic mechanisms to vary thrust direction and magnitude without rotating the entire pod, enhancing efficiency during acceleration or speed changes.^[18]^[5] The prime movers driving these propellers are typically electric or diesel engines. Electric configurations often employ AC synchronous or permanent magnet motors housed directly in the pod for gearless operation, delivering power outputs ranging from 1 MW to 20 MW, which supports high-efficiency thrust in applications like cruise ships and offshore vessels. Diesel-driven variants use internal combustion engines coupled to the propeller shaft, offering robust performance in workboats where electrical infrastructure may be limited.^[19]^[20] Steering is achieved by rotating the entire pod up to 360 degrees around a vertical axis, eliminating the need for a separate rudder. This rotation is facilitated by hydraulic rams or electric servo systems, where hydraulic setups use pressurized fluid to actuate rams connected to the pod's mounting, providing precise control under high loads, while electric servos offer responsive, low-maintenance alternatives through geared actuators. Gearing systems within the steering assembly transmit torque efficiently to enable rapid azimuth adjustments.^[9]^[21] Power transmission from the prime mover to the propeller occurs via shafting arrangements, such as Z-drive (horizontal input to vertical output) or L-drive (vertical input) configurations, which align the drivetrain within the compact pod. Clutches are integrated in hybrid or multi-input designs to engage or disengage power sources, simulating reverse thrust by allowing propeller reversal or pod reorientation without full engine stoppage in fixed-pitch systems.^[5]^[22]^[23] The dynamics of pod rotation are governed by the rotational torque equation \tau = I \alpha, where \tau represents the torque applied by the steering mechanism, I is the moment of inertia of the rotating assembly, and \alpha is the angular acceleration during azimuth turning. This fundamental relation ensures controlled maneuvering, with steering systems sized to overcome hydrodynamic resistances and achieve turning rates up to 25 degrees per second in typical designs.^[24]^[25]

Types

Conventional Azimuth Thrusters

Conventional azimuth thrusters represent the standard configurations employed in a wide array of marine vessels, providing 360-degree steerable propulsion through mechanical arrangements that integrate prime movers with rotatable propeller units. These designs prioritize reliability and efficiency for everyday applications, such as maneuvering in confined waters, and typically feature fixed- or controllable-pitch propellers driven by diesel engines or electric motors. The core mechanism involves a gear system that transmits power to the propeller while allowing full rotation around a vertical axis, enabling thrust redirection without auxiliary rudders.^[5] The Z-drive is a prevalent conventional design characterized by a horizontal input shaft from the prime mover, a vertical shaft within the rotating column, and a horizontal output shaft connected to the propeller. The L-drive is a related but distinct configuration with a vertical input shaft from the prime mover (often an electric motor) to a horizontal output shaft via bevel gears. This arrangement allows for compact installation and 360-degree rotation, making it suitable for vessels requiring precise control. Commonly used in inland waterway applications like push boats and ferries, Z-drives offer power outputs ranging from 200 to 2000 kW, balancing thrust needs with space constraints in riverine environments.^[26]^[27]^[28] Ducted designs incorporate a nozzle or shroud around the propeller to improve hydrodynamic efficiency, especially at low speeds below 10 knots, where they can generate up to 30% more thrust than open propellers by accelerating water flow and reducing tip losses. This enhancement is achieved through optimized nozzle profiles that minimize energy dissipation, making ducted azimuth thrusters ideal for operations demanding high bollard pull, such as harbor towing.^[29]^[30] Examples of conventional azimuth thrusters include the Voith-Schneider propeller (VSP), a cycloidal system with vertically adjustable blades on a rotating disk that enables instantaneous 360-degree thrust vectoring without mechanical rotation of the unit. VSP variants have been integrated into azimuth configurations for enhanced responsiveness in tugs and ferries, offering rapid changes in thrust magnitude and direction. Azimuth thrusters have seen widespread adoption in new tug constructions since the 2000s for improved maneuverability.^[31]^[32]

Specialized Variants

Podded propulsors, such as the Azipod system developed by ABB, represent a specialized evolution of azimuth thrusters where the electric drive motor is housed within a fully submerged, rotating pod mounted outside the ship's hull, enabling 360-degree thrust vectoring for enhanced maneuverability.^[19] This gearless design eliminates traditional shaft lines and gearboxes, reducing mechanical losses and improving hydrodynamic efficiency, particularly in demanding environments like icebreaking vessels where the pod's positioning allows for precise control in heavy ice conditions.^[33] Retractable azimuth thrusters are designed to minimize drag during high-speed transit by incorporating hydraulic lift mechanisms that allow the entire unit to fold upward into the hull when not in use, while deploying fully for azimuth operation to provide auxiliary propulsion and station-keeping capabilities.^[34] The retraction system typically employs telescopic hydraulic cylinders guided by rails, ensuring smooth deployment without increasing the vessel's draft or resistance, which is critical for dynamic positioning in offshore operations.^[35] Contra-rotating propeller (CRP) azimuth thrusters feature dual propellers rotating in opposite directions on concentric shafts within the azimuth unit, effectively canceling rotational torque and recovering rotational energy from the propeller slipstream to achieve efficiency gains of up to 15% compared to single-propeller configurations.^[36] This design enhances overall propulsion efficiency and reduces noise and vibration, making it suitable for applications requiring high maneuverability and low acoustic signatures, such as research vessels.^[37] In the 2020s, rim-driven thrusters have emerged as an advanced variant, integrating permanent magnet electric motors directly into the propeller rim to eliminate traditional drivelines, thereby reducing mechanical complexity, oil usage by 60-70%, and underwater noise while boosting fuel efficiency through minimized energy losses.^[38] Similarly, hybrid electric-diesel azimuth thruster setups combine diesel generators with battery storage and electric drives to optimize power delivery, enabling peak shaving and slow-speed electric operation that can reduce CO2 emissions by up to 30% through lower fuel consumption during variable load conditions.^[39] These configurations prioritize emissions compliance in regulated maritime zones by dynamically switching between power sources based on operational demands.^[40]

Operation and Control

Thrust Generation and Direction

Azimuth thrusters generate thrust primarily through the rotation of a propeller driven by an engine or motor via mechanical, electric, or hydraulic systems, where the magnitude of thrust is controlled by adjusting the propeller's rotational speed (RPM) or blade pitch, depending on whether a fixed-pitch or controllable-pitch propeller is used.^[41]^[9] In fixed-pitch configurations, thrust is varied by altering the engine or motor speed to change RPM, while controllable-pitch systems maintain constant RPM and adjust blade angle for precise thrust modulation, allowing efficient operation across different loads without reversing rotation.^[41] The resulting thrust output can be calculated using the standard propeller thrust formula T = \rho n^2 D^4 K_T, where \rho represents water density, n is the propeller rotational speed in revolutions per second, D is the propeller diameter, and K_T is the dimensionless thrust coefficient derived from propeller geometry and operating conditions.^[42] Direction control is achieved through real-time adjustment of the thruster's azimuth angle, enabling 360-degree rotation around a vertical axis to vector thrust in any horizontal direction without requiring a separate rudder.^[5]^[18] This rotation is typically powered by hydraulic or electric steering mechanisms, allowing seamless redirection of propulsion for maneuvering. Reverse thrust is produced either by rotating the thruster 180 degrees to redirect forward thrust astern or, in controllable-pitch systems, by reversing the blade pitch to generate negative thrust while maintaining the original orientation.^[43]^[41] The response time for full 360-degree rotation typically ranges from 10 to 30 seconds, influenced by the thruster's power rating, hydraulic system pressure, and environmental factors such as water currents, which can induce hydrodynamic loads that reduce rotational efficiency and increase torque requirements.^[44]^[45] Strong currents may cause the thruster to drift off the commanded angle, necessitating compensatory adjustments to maintain directional stability.^[1]^[46] Thrust generation and direction are monitored using integrated sensors that provide real-time feedback on key parameters, including propeller RPM, shaft torque, vibration levels, and hydraulic pressures, enabling automatic corrections for deviations in performance.^[47]^[48] Acceleration and speed sensors detect anomalies in thrust output, allowing systems to adjust RPM or pitch proactively to sustain optimal vectoring and prevent overloads.^[49]^[50]

Integration with Ship Systems

Azimuth thrusters integrate with a vessel's power supply through connections to main engines, generators, or battery systems, enabling flexible propulsion configurations such as diesel-electric, hybrid, or fully electric setups. In electric variants like the Azipod system, power is drawn from low- or medium-voltage sources including generators and batteries, with the gearless motor design optimizing energy efficiency by minimizing mechanical losses.^[19] Redundancy is achieved in dual-thruster configurations by incorporating separate power feeds and backup systems, such as double windings or redundant drives, ensuring continued operation if one unit fails, which is critical for dynamic positioning compliance in DP2 and DP3 classes.^[19]^[51] Control interfaces for azimuth thrusters typically include joystick controls for manual operation and automated systems for dynamic positioning (DP), with DP2 systems providing redundancy against single-point failures and DP3 adding protection against fire or flooding. Software platforms coordinate multi-thruster operations, processing inputs from sensors to allocate thrust and maintain vessel position, often integrating with vessel automation for seamless performance monitoring. Recent advancements include AI-driven thrust allocation algorithms and digital twin technologies for enhanced predictive control and optimization of multi-thruster operations as of 2025.^[5]^[52]^[53] Communication protocols such as CAN bus and Ethernet facilitate real-time data exchange between thrusters, sensors, and control units, supporting sensor feedback for steering and propulsion adjustments.^[54]^[55] Fail-safes like emergency stop functions are embedded in these protocols to halt operations instantly upon detecting faults, preventing potential hazards. Maintenance access for azimuth thrusters emphasizes remote diagnostics and modular designs to minimize downtime. Systems like ABB Ability enable predictive maintenance through digital monitoring, allowing remote analysis of thruster performance via internet-connected platforms.^[19] Modular components support straightforward replacement procedures, with some thrusters designed for exchange in as little as 48 hours without dry-docking, facilitated by condition monitoring tools that forecast failures based on parameter data.^[19]^[56] These features integrate with the ship's overall maintenance framework, ensuring reliability in demanding marine environments.^[57]

Applications

Commercial and Offshore Uses

In commercial shipping, azimuth thrusters enhance maneuverability for ferries and cruise ships, allowing precise docking and navigation in tight port spaces without heavy reliance on external tugs. These systems enable 360-degree thrust directionality, facilitating smoother operations for passenger vessels operating on short routes or in urban harbors. For instance, electric azimuth thrusters in ferries support zero-emission maneuvering in environmentally sensitive areas.^[58]^[58] A prominent example is the Royal Caribbean's Icon of the Seas, launched in 2024, which employs ABB's Azipod propulsion units— a type of azimuth thruster—for its primary power. Each of the three Azipod units delivers 20 MW, contributing to overall fuel efficiency improvements of up to 20% over conventional shaftline systems through optimized hydrodynamics and reduced wake.^[59]^[60] In offshore industries, azimuth thrusters are essential for supply vessels and floating platforms, providing dynamic positioning (DP) capabilities to maintain station-keeping amid currents and winds without anchors. This is particularly vital for oil and gas rigs, where vessels must hold precise locations during supply transfers or drilling support. Thruster configurations in these applications often integrate with DP systems for automated thrust allocation across multiple units.^[61]^[4]^[62] Tugboats leverage azimuth thrusters for harbor assistance, utilizing their 360-degree rotation for versatile push-pull maneuvers and escort towing of large ships during berthing or unberthing. Azimuth stern drive (ASD) tugs, equipped with dual thrusters at the stern, dominate this role due to their ability to generate high braking and flanking forces in confined waters.^[63]^[64] The widespread use of azimuth thrusters in these sectors drives economic benefits, including lower operational costs from fuel savings and decreased maintenance needs, alongside reduced crew requirements through automated control systems that minimize manual interventions. Industry reports project the global azimuth thrusters market to expand from $678.4 million in 2024 to $1.01 billion by 2030, fueled by demand in commercial and offshore applications.^[65]^[66]

Military and Research Applications

In military applications, azimuth thrusters enhance the maneuverability of warships and submarines, enabling precise and controlled movements critical for tactical operations. Retractable azimuth thrusters, in particular, are integrated into vessels like the U.S. Navy's Independence-class littoral combat ships (LCS), where a bow-mounted unit provides auxiliary propulsion and steering. This thruster pivots 360 degrees to direct thrust in any horizontal direction, allowing the ship to perform tight turns, lateral shifts, and rapid rotations at low speeds, which is essential for pier-side handling and anchoring without external assistance. In the LCS program, initiated in the early 2010s, these thrusters support emergency propulsion up to 5 knots and increase draft by about 5 feet when extended, offering tactical flexibility in near-shore environments. The final Independence-class ship, USS Pierre (LCS-38), was commissioned on November 15, 2025.^[67]^[68]^[69]^[70] Unique adaptations of azimuth thrusters for military use include shock-resistant designs tailored for combat durability. These retractable variants feature elastic deformation elements, resilient mountings, and rubber isolations to absorb impacts from underwater shocks, meeting stringent naval shock specifications such as those from MIL-S-901. Such reinforcements ensure operational reliability during high-intensity scenarios, as demonstrated in naval thruster solutions developed since the late 1970s. In research contexts, low-noise azimuth thrusters are employed to minimize acoustic interference during sensitive marine studies. These variants incorporate noise-optimized gearboxes and permanent magnet motors to reduce underwater radiated noise (URN), complying with international standards for environmental protection and enabling non-disruptive observations of marine life.^[71]^[72]^[73] Azimuth thrusters play a vital role in research vessels, particularly icebreakers navigating polar regions and platforms supporting deep-sea exploration. The German research icebreaker Polarstern, scheduled to enter service in 2030, is equipped with two Steerprop SP 160 PULL ARC LM azimuth propulsors, each delivering 9 MW of power through 4.8-meter propellers designed for Polar Class 2 (PC2) operations. These units enable the vessel to maintain 3 knots through 1.8 meters of multiyear ice with 20% snow cover, supporting year-round expeditions in the Arctic and Antarctic for up to 310 days annually. In deep-sea exploration, azimuth thrusters facilitate dynamic positioning on research vessels, crucial for deploying and maintaining Remotely Operated Vehicles (ROVs) during seabed surveys and scientific sampling. For instance, retractable models like the Thrustmaster TH1500MLR provide the stability needed for precise ROV operations in offshore environments.^[73]^[74]^[75] Case studies highlight the growing adoption of azimuth thrusters in high-stakes polar research by the 2020s. The U.S. Navy's LCS program, with deliveries starting in 2010, incorporated retractable azimuth thrusters on Independence-class ships to bolster littoral warfare capabilities, as seen in vessels like USS Independence (LCS-2), commissioned in 2010. In Antarctic expeditions, research fleets have increasingly relied on azimuth-equipped icebreakers; for example, new-generation vessels like the upgraded Polarstern represent a shift toward fully azimuth-propelled polar research platforms, enhancing navigation through extreme ice while reducing environmental impact through low-noise propulsion. By the mid-2020s, such systems have become standard in international Antarctic operations, supporting sustained scientific missions amid climate-driven challenges.^[67]^[76]^[73]

Performance Characteristics

Advantages

Azimuth thrusters provide superior maneuverability compared to traditional fixed-propeller systems with rudders, as their 360-degree rotatable design delivers omnidirectional thrust without the need for separate steering mechanisms, thereby eliminating rudder lag and enabling precise control in all directions.^[2] This capability results in faster response times during operations in confined waters, such as narrow ports or docking maneuvers, where ships can achieve optimal thrust alignment instantly and often without requiring tugboat assistance.^[5] For instance, crash-stop distances can be halved relative to conventional propulsion setups due to the direct vectoring of thrust.^[2] In terms of efficiency, azimuth thrusters can achieve up to 20% savings in fuel consumption through direct-drive configurations that minimize transmission losses, allowing vessels to maintain speed with less power input.^[77] Additionally, their design reduces wake turbulence behind the hull by positioning the propeller in cleaner water flow, improving overall hydrodynamic performance and further enhancing propulsion efficiency during transit.^[19] The compact footprint of azimuth thrusters frees up internal hull space that would otherwise be occupied by traditional shaft lines and rudders, enabling more flexible vessel layouts for cargo, crew, or equipment.^[2] This streamlined integration also contributes to lower maintenance requirements, as the systems typically feature fewer moving parts—such as eliminating complex gearbox assemblies—and in some designs, such as permanent magnet types, up to 50% less maintenance due to reduced wear.^[78] From an environmental perspective, azimuth thrusters facilitate integration with hybrid propulsion systems, where electric or battery-assisted drives can optimize engine loads and achieve significant reductions in emissions, including NOx and CO2, by operating auxiliaries more efficiently during low-demand phases.^[79] Moreover, their quieter operation—stemming from reduced mechanical vibrations and fewer cavitating components—minimizes underwater noise pollution, benefiting marine ecosystems in sensitive areas.^[80]

Disadvantages

Azimuth thrusters involve a high initial investment compared to conventional propulsion systems due to their complex manufacturing processes involving precision gearing, steering mechanisms, and integration with electric or hydraulic drives.^[28]^[81] This elevated upfront cost stems from the need for specialized materials and engineering to ensure 360-degree rotation and durability in marine environments, limiting adoption among smaller operators or vessels with budget constraints.^[82] Maintenance of azimuth thrusters presents significant challenges, as their submerged components, including propellers, bearings, and seals, are prone to biofouling from marine growth and accelerated wear from constant exposure to seawater and operational stresses.^[83] Repairs often necessitate dry-docking for major overhauls, such as bearing replacements or seal inspections, which can lead to extended downtime and increased operational costs if not addressed through proactive monitoring.^[56] These systems are vulnerable to physical damage from external hazards, including debris entanglement and ice impacts, which can cause structural stress and blade deformation. For instance, fishing gear fouling has led to seal breaches and costly thruster failures during operations.^[84] In icy conditions, propeller blades can experience significant stresses, such as over 100 MPa during ice impacts, risking hub damage and reduced functionality.^[85] Additionally, azimuth thrusters can experience cavitation, particularly at low speeds due to turbulent flow, where collapsing vapor bubbles erode propeller surfaces and diminish thrust efficiency.^[83] Operational limitations include reduced efficiency in shallow waters, where hydrodynamic effects such as increased flow blockage and wake alterations can decrease propulsive performance by altering thrust distribution.^[86] Electric variants also impose substantial power demands on the ship's electrical systems, often requiring 8-30 MW total capacity for multiple units, which can strain generators and necessitate oversized power plants to maintain reliability during dynamic positioning.^[87]

History and Development

Early Inventions

The origins of the azimuth thruster can be traced to early 20th-century innovations in steerable marine propulsion, with the Voith-Schneider Propeller (VSP) serving as a key precursor. Invented by Austrian engineer Ernst Schneider in 1927, the VSP featured a vertical-axis cycloidal design that generated thrust through oscillating blades arranged around a circular rotor, enabling precise directional control without a traditional rudder.^[88]^[89] This system, initially conceived as a hydroelectric turbine concept, was adapted for marine use by the Voith Group, providing 360-degree thrust vectoring via blade angle adjustments, which laid foundational principles for later azimuth technologies.^[90] Earlier concepts foreshadowed these developments, such as English inventor Francis Ronalds' 1859 "propelling rudder," which integrated propulsion and steering in a single rotatable unit to eliminate separate rudders. By the mid-20th century, advancements focused on pod-mounted propellers with rotatable housings. In 1950, German engineer Joseph Becker, founder of Schottel GmbH, invented the Z-drive transmission, a bevel-gear system allowing the propeller pod to rotate fully around a vertical axis while transmitting power from an inboard engine. This innovation addressed prior limitations in steering efficiency and was first commercialized as the Schottel Rudderpropeller, with initial installations on work vessels like hopper barges in the early 1950s.^[91] A pivotal milestone occurred in 1955 when the Pleuger company patented the first podded azimuth thruster design, featuring an electric motor directly in the submerged pod for simplified 360-degree steering. This under-ship configuration enhanced maneuverability for commercial vessels, marking the transition from experimental prototypes to practical applications. In 1965, Rolls-Royce delivered its first azimuth thruster, further advancing the technology through robust Z-drive implementations suited for larger ships, building on Schottel's foundational work.^[92] Early prototypes encountered significant engineering challenges, particularly in sealing the rotating interfaces to prevent water ingress and lubricant leakage under high pressure, as well as managing torsional torque in the bevel gears during full azimuth rotation.^[93] These issues, evident in initial Z-drive tests, required innovations in bearing materials and hydraulic steering systems to ensure reliability in marine environments, overcoming limitations that had plagued earlier rotatable pod designs.^[94]

Modern Innovations

In the late 20th century, a pivotal advancement in azimuth thruster technology emerged with the introduction of electric podded propulsion systems. In 1991, ABB launched the Azipod, a gearless, steerable electric propulsion unit that houses the motor within a pod outside the ship's hull, enabling 360-degree rotation and improved hydrodynamic efficiency.^[19] This innovation marked a shift toward fully electric azimuth thrusters, reducing fuel consumption by up to 20% compared to traditional shaftline systems and enhancing maneuverability for specialized vessels like icebreakers.^[95] Building on this foundation, the 2000s saw increased integration of azimuth thrusters with dynamic positioning (DP) systems, allowing precise station-keeping in offshore operations through coordinated thrust allocation and azimuth angle control.^[96] These developments facilitated reliable performance in challenging environments, such as oil and gas exploration, where thrusters maintain vessel position against currents and winds without anchors.^[97] Recent technological progress has focused on enhancing efficiency and environmental compatibility. Rim-drive thrusters, which eliminate traditional shafts and hubs by integrating the motor directly into the propeller rim, represent a notable post-2010s evolution; Kongsberg's Rim Drive Azimuth Thruster (RD-AZ), introduced in production models around 2015 with ongoing refinements documented in 2022, achieves higher propulsion efficiency through permanent magnet technology and reduced mechanical losses.^[98] Additionally, post-2020 innovations incorporate artificial intelligence for optimized control, using neural networks and reinforcement learning to dynamically adjust thrust allocation and azimuth angles in real-time, thereby improving energy efficiency in dynamic positioning scenarios by minimizing power usage during varying sea states.^[99] Such AI-driven systems adapt to environmental disturbances, reducing operational costs and emissions in vessels equipped with azimuth thrusters.^[100] Industry adoption has accelerated, particularly in energy-intensive sectors. In the 2010s, azimuth thrusters have been increasingly adopted in liquefied natural gas (LNG) carriers, particularly icebreaking variants, where dual or triple Azipod configurations enable year-round Arctic operations with superior icebreaking capabilities and fuel savings.^[101] This widespread integration stemmed from the need for enhanced maneuverability in confined ports and harsh conditions, with the first such vessel, the Christophe de Margerie, delivered in 2017.^[102] Regulatory pressures from the International Maritime Organization (IMO), including the 2020 sulfur cap and the 2023 GHG Strategy targeting a 20-30% reduction in carbon intensity by 2030, have further spurred hybrid azimuth thruster designs that combine electric pods with battery storage for low-emission modes during port maneuvers.^[103]^[104] Looking ahead, azimuth thrusters are evolving to support autonomous vessels and broader electrification trends. Their precise, software-controllable steering aligns well with unmanned surface vehicle (USV) requirements, as seen in designs like Kongsberg's UT 7623 SEV platform, which incorporates electric rim-drive azimuth units for remote operations.^[105] Market projections indicate significant growth, with the global azimuth thrusters sector expected to reach $1.01 billion by 2030, driven by electrification demands and IMO decarbonization goals.^[65] This trajectory underscores their role in sustainable maritime transport, including hybrid-electric systems that could achieve up to 30% efficiency gains in electrified fleets.^[106]

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Azimuth Thruster (Rexpeller®) - Kawasaki Heavy Industries
Since the propeller rotates 360 degrees around its vertical axis, the thruster can perform double duty, propelling as well as steering a vessel. Able to ...
[19]
Azipod® electric propulsion Marine & Ports | Systems and Solutions
Azipod propulsion is a gearless steerable propulsion system where the electric drive motor is housed within a pod outside the ship hull.
[20]
[PDF] Z and L Drive Propulsion and Thrusters Z ... - Thrustmaster of Texas
Hydraulic Z-Drive thrusters are available up to 2000hp (1500kW) for either steerable or non-steerable azimuth applications. Hydraulic Z-Drives are especially ...
[21]
Dynamic Response Characteristics of the Hydraulic Rotary System ...
Feb 9, 2023 · ... hydraulic rotary system of the azimuth thruster ... a simulation model of the servo control hydraulic thruster of a remotely operated vehicle.
[22]
Azimuth Thrusters - Twin Disc
The Veth Hybrid Drive Thruster is a Z-Drive thruster equipped with two input shafts—one for a diesel engine with a clutch and one for an electric motor. The ...
[23]
Clutches for Marine Applications
Logan PTO clutch mounted to the live PTO pad of a ZF 280 series marine transmission. Logan CH and HPC clutches for Ulstein Aquamaster Azimuth thrusters.
[24]
Estimation of propeller torque in azimuth thrusters - ResearchGate
Aug 10, 2025 · In this paper, the problem of estimating unknown propeller torque excitations and angular velocities in an azimuth-thruster driveline is ...Missing: rotational | Show results with:rotational
[25]
General formulation of an analytic and Lipschitz continuous control ...
We consider as motors parameters : the maximum and minimum azimuth rate of change per second as Δ β m a x = 25 ∘ \Delta\beta_{max}=25^{\circ} , Δ β m ...
[26]
Well Mounted Azimuth Thrusters - ZF
Well Mounted Azimuth Thruster of ZF enables excellent maneuverability ✓high reliability✓ for all high performance application✓100 to 2500 kW ▻ More.
[27]
Azimuth thruster - Well - ZF Italy - built-in / for boat / electric
30-day returnsThe thruster can be delivered in a performance range of 200-2000 kW.The thruster can be found in high performance applications as river going passenger ...Missing: common inland
[28]
Z-Drives - Thrustmaster of Texas
Z-Drive azimuthing thrusters provide maximum thrust in any direction, independent of vessel speed, offering superior pinpoint maneuverability under all ...Missing: common range 200-2000
[29]
Bow Thrusters, Tunnel Thruster, Stern Thrusters, Dynamic Positioning
Bow/Tunnel Thrusters are used for maneuvering, installed in the bow, sometimes stern, and provide 180° thrust for precise control.
[30]
Thrusters - Wärtsilä
- Azimuthing thruster – A propeller that can be rotated through 360° in the horizontal plane, thus allowing the thrust to be generated in any desired direction.
[31]
Azimuth Thruster with Push Ducted Propellers - Brunvoll
Increase propulsion efficiency by applying the optimum nozzle profile. A ducted propeller gives up to 30% higher thrust at low speed compared to an open ...
[32]
https://www.schottel.de/en/media-events/press-releases/press-detail/robert-allan-and-schottel-celebrate-milestone-of-500-tugs
[33]
[PDF] Thrusters - Dynamic Positioning Committee
Contrary to all other types of azimuth thrusters (thrust changes accordingly to polar coordinates), the thrust is varied on the basis of X/Y logic. Fig. 1 shows ...<|control11|><|separator|>
[34]
Robert Allan and SCHOTTEL celebrate milestone of 500 tugs
Since 2000 more than one third of all Robert Allan azimuth tug designs have been fitted with SCHOTTEL propulsion systems, including RAscal, RAstar, RAmparts, ...
[35]
ABB further enhances efficiency of Azipod® electric propulsion with ...
Jul 5, 2021 · ABB Azipod® propulsion is a gearless steerable propulsion system where the electric drive motor is in a submerged pod outside the ship's hull.
[36]
Retractable azimuthing thruster - Kongsberg Maritime
Retractable thrusters provide the enhanced manoeuvring capability of an azimuth thruster while adding no draught or running resistance to the vessel.
[37]
Marine Retractable Azimuth Thruster - Hi-Sea Marine
The retractable mechanism is telescopic by the hydraulic cylinder to drive the azimuth thruster up and down. Moreover, the guide rail is used to increase the ...<|separator|>
[38]
Energy saving performance analysis of contra-rotating azimuth ...
The energy saving performance of contra-rotating azimuth propulsor (CRAP) is investigated based on low order potential-based panel method.
[39]
[PDF] Contra-Rotating Propellers – Combination of DP Capability, Fuel ...
CRP Azimuth Propulsors are designed for the applications requesting high propulsion efficiency, low noise and vibration, and Omni directional manoeuvrability.
[40]
Rim Drive Azimuth Thruster (RD-AZ) - KONGSBERG
The compact, highly efficient direct electric Rim Drive azimuth thruster uses a permanent magnet motor for advanced vessel manoeuvrability and lower fuel use.Missing: principles | Show results with:principles
[41]
First Environmentally Friendly Next-Generation Electric Propulsion ...
First Environmentally Friendly Next-Generation Electric Propulsion Ship System in Japan System integration enabling to reduce CO2 emissions by 30%. IHI Power ...
[42]
Investigation of hybrid power plant configurations for an offshore ...
Aug 1, 2023 · [12] concluded that integration of batteries with conventional engines in offshore supply vessels reduces the emission from 20 % up to 45 %, ...
[43]
[PDF] Propulsion and Thrusters - Dynamic Positioning Committee
Oct 22, 1997 · The fixed pitch propeller must be driven by a variable speed drive in order to adjust and if necessary reverse the thrust. The controllable ...Missing: RPM | Show results with:RPM<|separator|>
[44]
A Numerical Study on Modeling Ship Maneuvering Performance ...
Nov 13, 2023 · This study presents a method of maneuverability study for the ship with two azimuth thrusters using CFD numerical calculation. As a specific ...
[45]
Azimuth mount for the T100 / T200 series - DIY USVs
Dec 23, 2014 · The thrusters can run in reverse - have you considered using 180 degree rotation combined with forward and reverse thrust to provide thrust in ...
[46]
Are Azimuth Thrusters Always the Best DP Solution? - LinkedIn
Mar 16, 2022 · This can take from 10 to 20 seconds and it will need to hunt a bit to maintain surge control.
[47]
Azimuth Thruster capabilities - Dynamic Positioning - gCaptain Forum
Oct 26, 2012 · Ours will do one full rotation in 30 seconds. The thrusters are ... If it is 24 secs or higher, we change the filters and every other time there ...
[48]
What is the efficiency of a mounted azimuth thruster? - Blog
Sep 15, 2025 · The efficiency of a mounted azimuth thruster can vary depending on the operating conditions. Factors such as the vessel's speed, load, and sea ...
[49]
[PDF] PCMS Propulsion Condition Monitoring Service - Wärtsilä
Data from sensors that measure vibration, hydraulic pressures and tem peratures are combined with operational parame ters of the thrusters such as setpoint and ...
[50]
Thruster Feedback Pt 1 - Overview - LinkedIn
Jan 6, 2022 · Direct control reference – This feedback is used to directly control thrust output. If it is wrong then the thrust will be wrong. If the thrust ...
[51]
Probabilistic Condition Monitoring of Azimuth Thrusters Based on ...
This study introduces a condition monitoring algorithm using acceleration and shaft speed data to detect anomalies that give information on the defects in the ...
[52]
[PDF] Health Monitoring of Steerable Thrusters
Sensors. Sensor technology is the base of Health Monitoring. The following sensors are used in addition to the sensors already present in the normal ...
[53]
What Is DP (Dynamic Positioning) ? A Complete Guide - Seavium
Dec 22, 2024 · Azimuth thrusters, tunnel thrusters, and main propellers adjust in real time to maintain stability. DP Classes: DP1, DP2, and DP3. The DP ...
[54]
Dynamic Positioning Control Systems - KONGSBERG
Dynamic Positioning (DP) systems automatically maintain a vessel's position and heading using integrated sensors, thrusters, and control algorithms.Missing: azimuth | Show results with:azimuth
[55]
What are the communication interfaces of Azimuth Retractable ...
Sep 11, 2025 · In an Azimuth Retractable Thruster control system, the CAN bus can be used to connect the main control unit to various sensors and actuators.
[56]
[PDF] Propulsion Control System - Praxis Automation Technology
Mega-Guard PCS can also communicate with thrusters and engines through. Ethernet and various serial protocols. One I/O module is sufficient for standard ...
[57]
[PDF] Preventive maintenance methods for heavy duty azimuthing thrusters
These online diagnostic systems measure important parameters and help to forecast unexpected failures and enhance preventative maintenance.Missing: modular | Show results with:modular<|control11|><|separator|>
[58]
US type azimuthing thruster - Kongsberg Maritime
US thrusters have been the obvious choice for ship applications where reliability and performance really matter, which is proven by over 7000 globally ...<|control11|><|separator|>
[59]
Marine Thruster Azimuth in the Real World: 5 Uses You'll Actually ...
Oct 16, 2025 · Azimuth thrusters facilitate safer, more efficient port operations. Ships can maneuver in tight spaces with minimal reliance on tugs. Cruise ...
[60]
LNG-powered Icon of the Seas completes propulsion start trial
May 12, 2023 · ... Azipod propeller system has a power of 20 MW. The Icon's construction started in June 2021 and an LNG fuel tank was installed in November 2021.
[61]
Mid-Range Azipod: Powering Fincantieri's Cruise Vessels - gCaptain
Mar 28, 2023 · Azipod® propulsion also improves a ship's hydrodynamic performance and cuts fuel consumption by up to 20 percent compared with a traditional ...
[62]
OSV - Thrustmaster of Texas
Dynamic positioning capability has become the norm for today's Offshore Supply Vessels. Thrustmaster tunnel and azimuth thrusters are used by all major ...
[63]
Vessel DP Equipment: Thrusters, Sensors, and Control Systems
Azimuth thruster capabilities: ▻ Full 360-degree rotation capability ▻ Independent thrust magnitude and direction control ▻ Fixed or retractable ...<|separator|>
[64]
Tugs - Wärtsilä
- Azimuthing Stern Drive (ASD) tug, stern drive azimuth tug – The tug with two azimuth thrusters under the stern. ASD tugs perform the majority of towing ...
[65]
NTSB Urges Speed Limits for ASD Tugs During Harbor-Assist ...
Sep 21, 2023 · ASD tugs are equipped with two azimuth thrusters under the stern and are designed for push-pull, harbour assist and escort towing. ASD tugs ...
[66]
Azimuth Thrusters Market Size ($ 1.01 Billion) 2030
The Global Azimuth Thrusters Market will witness a robust CAGR of 5.9%, valued at $678.4 million in 2024, and is expected to appreciate and reach $1.01 ...Missing: impact crew
[67]
North America 360 Degree Azimuth Thruster Market Size 2026
Oct 27, 2025 · High Capital Investment: The initial cost of azimuth thrusters and associated retrofitting can be prohibitive, especially for smaller operators.
[68]
Driving Independence-variant Littoral Combat Ships | Proceedings
A waterjet system propels the Independence-variant LCS, with four steerable Wärtsilä waterjets at the stern and a retractable azimuthal (azi) thruster near the ...
[69]
Celebrating 190 Years of Excellence: L3Harris Calzoni's Legacy in ...
Apr 14, 2025 · This technology is currently being utilized in three of the company's ongoing projects: an azimuth thruster for submarines that aids in ...
[70]
Independence class LCS Littoral Combat Ship US Navy Austal
1 x retractable bow-mounted azimuth thruster. Armament: 1 x Mk.110 57mm gun weapon system 1 x Mk.15 Mod.31 SeaRAM CIWS for RIM-116 Rolling Airframe Missiles ...
[71]
Retractable Azimuth Thruster - Shock qualified design - Brunvoll
Elastic deformation, resilient mounting and rubber isolation provide shock absorption in compliance with naval specifications.
[72]
[PDF] Trusted for shock qualified naval thruster solutions worldwide
Brunvoll has pioneered the development of retractable azimuth thruster technology for naval applications since 1979. Brunvoll developed and produced retractable ...
[73]
Steerprop to deliver world's largest mechanical azimuth propulsors ...
Sep 15, 2025 · Finnish propulsion expert Steerprop has been selected to power the new Polarstern, Germany's next-generation polar research icebreaker, ...
[74]
Groundbreaking research vessel New Polarstern - TKMS
Equipped with two state-of-the-art azimuth thrusters from Steerprop, Polarstern boasts rotatable propeller nacelles built to ice class PC2 standards. These ...Missing: Azipod | Show results with:Azipod
[75]
Research Vessels - Thrustmaster of Texas
Vessels are fully equipped with state-of-the-art scientific instrumentation, laboratories and IT equipment and are used for seismic surveys of the seabed floor.
[76]
USS Independence LCS-2 - Military Power - MotorTrend
Feb 1, 2010 · The U.S. Navy's Littoral Combat Ship (LCS) program began back in ... Bow Thruster:Two retractable azimuth. Maximum Speed:More than 45 ...
[77]
Top 5 Benefits of ZF Marine's Industry-Leading Thrusters
Sep 27, 2023 · Many customers report saving between 10 to 20 percent in fuel costs, as compared to a traditional shaft line vessel.
[78]
Rolls-Royce Unveils Permanent Magnet Azimuth Thruster at ...
Jun 4, 2015 · Very few moving parts means very little maintenance – up to 50 percent less according to Rolls-Royce; Less moving parts results in 50 percent ...Missing: fewer | Show results with:fewer
[79]
Award-winning M/Y "Vanadis": First hybrid yacht propelled by ...
Award-winning M/Y "Vanadis": First hybrid yacht propelled by SCHOTTEL azimuth thrusters · Lower fuel consumption, lower environmental impact. The propulsion ...
[80]
Discover the Benefits of Electric Direct-Drive Thruster Technology
Sep 6, 2022 · Direct-drive thrusters reduce driveline losses, offer 360° rotation for maneuverability, lower noise/vibrations, and reduce fuel burn and ...Fundamental Advantages · Set For Success · Growing Demand<|separator|>
[81]
Global Azimuth Thrusters Market Size, Share, Forecast To 2033
High initial costs associated with the design, manufacturing, and installation of azimuth thrusters can be a significant barrier for shipowners, especially ...
[82]
The global Azimuth Thrusters market size will be USD 536.6 million ...
High Initial Expenses Will Limit Market Growth. The growth of the azimuth thruster market is severely hampered by the high startup expenses. Purchasing ...
[83]
What are the performance limitations of an Azimuth Thruster? - Blog
### Performance Limitations of an Azimuth Thruster
[84]
Costly damage to azimuth thruster caused by fishing gear
Sep 17, 2018 · Rope and fishing net fouling found on the starboard azimuth thruster. The seal was damaged by the fishing net. Seawater presence was ...Missing: issues | Show results with:issues
[85]
[PDF] Numerical Analysis of Ice Impacts on Azimuth Propeller - DTIC
Not only can propeller ice interaction result in propeller blade damage, the stress and loads place on the propeller could result in shafting or engine failures ...Missing: vulnerabilities debris
[86]
Research on the effect of shallow draft on the performance of ...
Jun 15, 2024 · The stagnation inlet boundary condition predicts the azimuth thruster bollard performance more accurately and the flow field streamlines more ...Research Paper · 4. Results And Discussion · 4.2. Shallow Draft Effects
[87]
[PDF] Maritime Electrical Installations And Diesel Electric Propulsion
Apr 22, 2003 · Like the conventional azimuth thruster, the podded propulsion unit is freely rotate-able and may produce thrust any direction. The main ...
[88]
Voith Schneider Propeller (VSP)
This unique vessel propulsion solution was developed 90 years ago by Austrian engineer Ernst Schneider. Today, Voith Schneider Propellers are in use all over ...
[89]
Numerical Investigation of the Performance of Voith Schneider ...
Nov 6, 2015 · The research explained in this article was carried out to investigate the numerical hydrodynamic characteristics of the Voith Schneider Propeller (VSP) system.<|separator|>
[90]
The fascination of the Voith Schneider Propeller (VSP)
Ernst Schneider began working on the development of propellers as early as 1923. His first idea, a “screw propeller with a bird's wing profile”...
[91]
Azimuth thruster - Wikipedia
An azimuth thruster is a configuration of marine propellers placed in pods that can be rotated to any horizontal angle (azimuth), making a rudder redundant.Types of azimuth thrusters · Advantages and disadvantages · History
[92]
Z-drive - Wikipedia
Origins. The Z-drive transmission was invented in 1950 by Joseph Becker, the founder of Schottel, and used in the first azimuth thrusters built by Schottel ...
[93]
SCHOTTEL RudderPropeller: The Leading Invention since 1950
Jun 30, 2025 · SCHOTTEL founder Josef Becker revolutionized marine propulsion technology with his invention of the fully steerable rudder propeller.
[94]
Rolls-Royce marks azimuth thruster milestone - Marine Log
At an event in Rauma, Finland, Rolls-Royce this week celebrated the 50 year anniversary of its first azimuth thruster ...Missing: history | Show results with:history
[95]
[PDF] Thruster Experience- Seal Issues - Dynamic Positioning Committee
Problems in both categories. • mostly due to: in some cases: insufficient knowledge of products/applications. (example: vibration effects).Missing: early development torque
[96]
Design and characterization of a small-scale azimuthing thruster for ...
It is difficult to accurately control the thrust output of such a small unit by regulating motor torque or power due to the relatively large influence of ...Missing: early | Show results with:early
[97]
https://ww2.eagle.org/content/dam/eagle/rules-and-guides/archives/other/191_dpsguide1/DPS_Guide_e-May18.pdf
[98]
[PDF] Past, Present and Future of Hydrodynamic Research for DP ...
By assuming a quadratic relation between power and thrust, this results in a linear system of equations to determine the thruster RPMs and azimuth angles.
[99]
[PDF] DYNAMIC POSITIONING SYSTEMS
Thruster System: All components and systems necessary to supply the DP system with thrust force and direction. The thruster system includes: i). Thrusters with ...
[100]
[PDF] Rim Drive Azimuth Thruster (RD-AZ) | Kongsberg
The Rim Drive Azimuth Thruster is an environmentally friendly thrus- ter from KONGSBERG. The highly efficient PM motor, with no requ- irement for an internal ...Missing: prototype 2022
[101]
[PDF] integrating artificial intelligence into ship course-keeping systems
Azimuth thruster control systems integrate multiple sensors and use neural net- works for optimal thrust allocation and direction control. The adaptive laws ...Missing: post- | Show results with:post-
[102]
Reinforcement Learning-Based Tracking Control of USVs in Varying ...
We present a reinforcement learning-based (RL) control scheme for trajectory tracking of fully-actuated surface vessels.
[103]
Icebreaking LNG carriers: propulsion solutions enabling efficient ...
Dec 8, 2021 · This paper will introduce selected operational results from the revolutionary icebreaking LNG carriers with modern azimuth propulsion systems.
[104]
2023 IMO Strategy on Reduction of GHG Emissions from Ships
The 2023 IMO GHG Strategy envisages, in particular, a reduction in carbon intensity of international shipping (to reduce CO 2 emissions per transport work), as ...
[105]
ZF Launches Hybrid of new Azimuth Thruster - ZF Press Home
Sep 5, 2022 · It allows for full electric sailing and manoeuvring, which is especially useful in ports or waterways with strict emission and noise regulations ...<|separator|>
[106]
[PDF] Kongsberg Maritime
Patents on concepts and designs for an azimuth thruster were issued in the United. States and the United Kingdom throughout the 19th century. Engineers only ...
[107]
Electric Ship Market Size, Share, Trends & Growth Analysis 2032
The electric ship market is expected to reach USD 18.39 billion by 2032, from USD 4.85 billion in 2025, with a CAGR of 21.0%.