Fact-checked by Grok 2 weeks ago

Suezmax

A Suezmax is a term denoting the largest ship dimensions capable of transiting the in a fully laden condition, primarily applied to oil tankers optimized for this route. These vessels are constrained by the canal's specifications, including a maximum of 20.1 meters (66 feet), a of up to 50 meters at full draft, and a length generally limited to around 275 meters, allowing for a (DWT) typically between 120,000 and 200,000 tons. The Suezmax class emerged in response to the Suez Canal's historical and ongoing size restrictions, which have evolved through expansions to facilitate larger vessels while balancing navigational safety and infrastructure capacity. Originally limited to smaller ships upon the canal's opening in —with depths of about 8 meters and maximum loads of 5,000 tons—the waterway's deepening and widening, particularly after the and expansions, raised the permissible draft to 20.1 meters and increased the cross-sectional area to support up to 240,000 DWT loads, though practical Suezmax designs adhere to the 50-meter beam limit for laden transits to maximize efficiency. These expansions enabled the canal to handle 61.2% of the global tanker fleet and 92.7% of bulk carriers as of recent assessments, underscoring its role as a critical for . Primarily used for transporting crude oil, , and bunker fuel on long-haul routes between the and or the , Suezmax tankers offer a balance of economy and versatility, avoiding the need for operations that larger very large crude carriers (VLCCs) often require for passage. Their design prioritizes compliance with the 's limit of 68 meters and bottom clearance requirements, ensuring unhindered passage without compromising stability or speed, typically around 13-15 knots when loaded. In the broader maritime context, Suezmax vessels represent an intermediate size class between (80,000-120,000 DWT) and VLCCs (over 200,000 DWT), playing a pivotal role in global energy logistics amid fluctuating tolls and geopolitical considerations affecting routes.

Definition and Dimensions

Definition

A Suezmax is a naval architecture term referring to the largest ship measurements capable of transiting the in a fully laden condition without the need to unload cargo. This classification ensures vessels can navigate the waterway efficiently while carrying their maximum payload, optimizing global trade routes that avoid longer alternatives like the . The term originates from the Suez Canal's pivotal role in establishing the maximum permissible dimensions for ships to achieve economical passage through this critical maritime chokepoint. It reflects the canal's influence on ship design standards in the shipping industry, where adherence to these limits enables direct access to key markets in , , and the . Unlike transits in an unladen or partially loaded state, which might allow for larger vessels, the Suezmax standard specifically emphasizes the fully laden condition to represent real-world operational viability and cargo efficiency. This distinction underscores the practical constraints imposed by the canal's geographical and engineering features on loaded vessel stability and maneuverability.

Key Dimensions and Constraints

Suezmax vessels are defined by the physical constraints of the , which operates without locks, relying on its channel depth, width, and overhead clearance to accommodate transit. The 's channel depth of 24 meters permits a maximum laden of 20.1 meters, providing under-keel clearance to prevent grounding while navigating the lock-free . This limit directly influences calculations, as the vessel's underwater volume must not exceed the available to maintain and during passage. The maximum (LOA) for Suezmax vessels typically ranges from 275 to 285 meters, allowing them to maneuver through the canal's bends and passing sections without requiring special permissions. The , or width, is constrained to up to 50 meters to fit within the canal's effective width at the maximum , particularly in narrower legacy sections that persist post-2015 ; wider beams up to 77.5 meters are allowed at shallower drafts, such as 12.2 meters. Laden draft is capped at 20.1 meters, corresponding to an limit of approximately 68 meters above the to clear bridges and overhead structures. (DWT) for Suezmax vessels generally falls between 120,000 and 200,000 tons, with tankers often at the higher end to maximize cargo capacity within these dimensional bounds. These parameters ensure compliance with the canal's cross-sectional area limits, where wetted surface and are calculated to prevent excessive or during .

Historical Development

Suez Canal Expansions

The Suez Canal opened on November 17, 1869, with initial dimensions that severely limited vessel sizes, featuring a length of 164 kilometers, a depth of 8 meters, a bottom width of 22 meters, and a surface width ranging from 61 to 91 meters, accommodating ships up to approximately 5,000 deadweight tons (DWT). These constraints reflected the era's maritime technology, restricting transits to smaller steamships and sail vessels primarily engaged in regional trade. In 1956, nationalized the under President , prompting the and international tensions that briefly disrupted operations but did not immediately alter physical dimensions. The canal's closure from 1967 to 1975, triggered by the and subsequent conflicts, required extensive clearance of blockages including sunken ships and debris before reopening on June 5, 1975. Upon reopening, the channel was deepened to 16.1 meters (53 feet) to restore and enhance capacity for post-war shipping demands. A major expansion project from 2010 to 2015, known as the New Suez Canal initiative, significantly upgraded the by widening sections and deepening the channel to a maximum draft of 20.1 meters (66 feet), enabling laden transits of larger vessels and increasing daily capacity from 49 to up to 97 ships. This US$8 billion effort included constructing a 35-kilometer parallel channel and existing bypasses, reducing transit times and accommodating the growth in global container and tanker traffic. Ongoing improvements from 2023 to have further enhanced the canal's , including widening the dual-lane portion from 72 kilometers to 82 kilometers to support two-way traffic more efficiently, with these changes becoming fully effective by November . These upgrades, including a 10-kilometer extension tested in late 2024 and operational in early , aim to boost daily ship capacity by 6 to 8 additional vessels and improve navigational safety by 28 percent through reduced current impacts, while the maximum draft remains at 20.1 meters as of November .

Evolution of Suezmax Classification

The Suezmax classification emerged as a standard for vessels optimized to transit the without offloading cargo, with its parameters evolving in tandem with canal infrastructure upgrades and the demands of . Prior to the canal's in due to geopolitical conflict, the maximum permissible draft of approximately 12 meters restricted Suezmax vessels to around deadweight tons (DWT), primarily accommodating smaller tankers suited to the era's shallower and narrower constraints. This limit reflected the canal's original design from the late , progressively deepened but still inadequate for the larger ships emerging in post-World War II shipping. Following the canal's reopening in 1975, significant increased the allowable to 16 , elevating the Suezmax to 150,000 DWT and enabling the of substantially larger crude oil carriers, which aligned with the global shift toward in bulk shipping. Subsequent deepenings raised the to 17.7 by , 18.9 by 2000, and 20.1 by 2010, further refining these parameters and bridging the gap between operational efficiency and infrastructural feasibility. This post-reopening adjustment marked a pivotal expansion in classification standards, as shipbuilders began designing vessels to maximize cargo while adhering to the canal's updated length and beam tolerances, thereby reducing reliance on longer routes for oversized tankers. From 2015 onward, the New Suez Canal project—featuring a parallel 35-kilometer channel—has solidified the Suezmax standard at a maximum of 240,000 DWT, incorporating fine-tuned allowances for beam up to 50 meters at full draft of 20.1 meters (with absolute maximum of 77.5 meters at reduced draft) and overall length up to approximately 275 meters (absolute maximum 400 meters) to enhance bidirectional throughput and minimize delays. These modifications responded to surging global trade volumes, particularly in energy commodities, by permitting fuller utilization of the canal's cross-sectional area without exceeding structural limits. The 2015 expansion built upon prior deepenings to 20.1 meters draft achieved by 2010, standardizing the class for modern dry bulk and liquid cargo carriers. Parallel to infrastructural changes, the evolution of Suezmax classification has been profoundly shaped by () regulations emphasizing safety and , which have imposed design constraints that influence maximum size and configuration. For instance, the amendments to mandating double-hull construction for oil tankers to prevent spills necessitated broader beams and adjusted proportions for Suezmax vessels, ensuring compliance while fitting canal dimensions and maintaining DWT efficiency. Similarly, SOLAS conventions on structural integrity and stability have driven iterative refinements in hull forms and compartmentalization, prioritizing risk mitigation in narrow-channel navigation over sheer capacity gains. These regulatory imperatives, continually updated to address collision risks and pollution, have ensured that Suezmax designs balance commercial viability with international standards, adapting to both canal constraints and broader maritime governance.

Vessel Types

Oil Tankers

Suezmax oil tankers are designed with a typical (DWT) ranging from 125,000 to 200,000, allowing them to maximize cargo loads while adhering to the dimensional constraints of the . This size class is particularly optimized for the long-haul of crude from production hubs in the to refineries in and , where the vessels' capacity enables efficient delivery without requiring larger ships that exceed canal limits. These tankers play a key role in balancing trade routes, as their dimensions permit fully laden transits, reducing the need for operations that could increase costs and environmental risks. A defining feature of Suezmax oil tankers is their double-hull construction, mandated by the International Convention for the Prevention of Pollution from Ships (MARPOL) for all oil tankers over 5,000 DWT to enhance structural integrity and minimize risks in the event of collisions or groundings. Complementing this, they incorporate segregated ballast tanks (SBTs), which are dedicated compartments for clean water ballast separate from cargo areas, ensuring vessel and during Suez Canal transits where and speed restrictions demand precise control. These SBTs, often protectively located along the hull sides and bottom, comply with () standards for damaged and allow safe navigation through the canal's narrow channels without compromising safety. In terms of cargo handling, Suezmax tankers can accommodate approximately 1 million barrels of crude , equivalent to about 159,000 cubic meters, depending on the specific configuration and . Pumping systems are engineered with capacities that support efficient loading and discharge, typically up to 12,000 cubic meters per hour overall, but adjusted to maintain under transit conditions where operational speeds are limited to around 8 knots. Representative examples include the Sonangol Kulumbimbi, a 157,000 DWT Suezmax tanker delivered in 2023, built by Samho Shipyard for Angola's state-owned Sonangol Shipping, highlighting the class's ongoing production by leading South Korean shipbuilders.

Dry Bulk Carriers

Suezmax dry bulk carriers are specialized vessels designed to transport unpackaged solid commodities such as iron ore and coal through the Suez Canal, maximizing payload within the waterway's dimensional constraints. These ships typically feature a deadweight tonnage (DWT) ranging from 120,000 to 200,000 tonnes, allowing them to carry substantial volumes of dense bulk cargoes while adhering to canal limits on length, beam, and draft. Their gearless construction, lacking onboard cranes or derricks, optimizes structural integrity and cargo space for efficient passage, as onboard handling equipment would add unnecessary weight and complexity during transit. The cargo holds in Suezmax dry bulk carriers are engineered with box-shaped configurations to enhance stowage efficiency for high-density materials like , minimizing voids and maximizing volumetric capacity. These s usually incorporate 9 large holds, divided by watertight bulkheads for cargo segregation and stability, with wide hatch openings that facilitate rapid filling and emptying. This design prioritizes the transportation of homogeneous bulk loads over mixed cargoes, ensuring structural strength under the stresses of heavy loading. Loading and unloading operations for Suezmax dry bulk carriers rely exclusively on shore-based infrastructure, such as grab cranes, conveyor systems, or ship loaders, due to the gearless nature of the and the strict time limits imposed during Suez Canal transits. This dependency streamlines port turnaround times but requires coordination with equipped terminals to handle the large volumes efficiently, often using chutes for loading and integrated grabs for discharge. Representative examples include variants adapted to Suezmax dimensions, bridging the gap between traditional and larger designs to fit canal constraints while maintaining high-capacity transport capabilities.

Container Ships

Suezmax container ships represent a specialized subset of container vessels optimized for transit through the Suez Canal, balancing cargo efficiency with the waterway's dimensional restrictions. Unlike the dominant association of the Suezmax classification with oil tankers, these ships prioritize standardized , typically accommodating 10,000 to 18,000 twenty-foot equivalent units (TEU) or more. This capacity positions them as an intermediate class larger than types, with even some ultra-large container vessels (ULCVs) capable of transiting the canal. Their design emphasizes canal compatibility, with lengths approaching 400 meters and beams up to around 61 meters to fit the canal's cross-section while maximizing bays. Key design adaptations include wider beams relative to earlier generations, often around 50–61 meters, which enhance transverse during one-way traffic in the narrow sections. This broader profile helps mitigate risks from shallow water effects and cross-currents, allowing safer navigation without compromising speed or . Additionally, stacking and lashing systems are engineered for 18–20 heights , constrained by the Suez 's maximum of 68 meters above the ; this limit ensures clearance under bridges and overhead structures while optimizing vertical space utilization. Such configurations permit secure lashing of high-stacked containers against wind loads prevalent in the region. Representative examples of Suezmax container ships include vessels like the Edison, a 13,100 TEU carrier built to canal specifications, serving intra-Asia-Europe trade lanes via transits. These "Suezmax" and mainline vessels, such as conceptual designs like the 11,000 TEU Suez Max SS, demonstrate how operators leverage the class for reliable, high-volume container flows without requiring alternative routes like the . By focusing on canal-optimized hull forms and modular container arrangements, these ships contribute to efficient global supply chains, particularly for mid-sized trades.

Operations and Navigation

Transit Requirements

Transit through the Suez Canal for Suezmax vessels, which are designed to the canal's maximum permissible dimensions, requires strict adherence to procedural and regulatory protocols enforced by the (). Pilotage is mandatory for all transits, with -appointed pilots boarding vessels at for northbound journeys or for southbound ones to ensure safe navigation through the canal's narrow channels and lakes. For larger Suezmax vessels, particularly those exceeding certain or limits, tug assistance is often required during , unmooring, and critical maneuvers to enhance safety and prevent grounding. The operates a structured system to manage efficiently, with northbound and southbound convoys typically forming daily and operating in one or two directions depending on the . Vessels proceed at controlled speeds of approximately 8 to 10 knots (15 to 18.5 km/h), adjusted for vessel type—such as lower speeds for tankers—to maintain convoy spacing and avoid wake-induced erosion of the canal banks. Slot allocations are assigned based on arrival notifications submitted at least five days in advance, prioritizing vessels that meet dimensional and operational criteria, with delays possible during peak periods. Documentation requirements include submission of the vessel's registry certificate, , crew list, and cargo manifest to the prior to . fees are calculated based on the vessel's Suez Canal Net Tonnage (SCNT), with tiered rates in (SDR) per ton— for example, lower rates for the first 10,000 SCNT escalating for higher tonnages—plus additional charges for pilotage and tugs. Surcharges apply for oversized dimensions beyond standard limits or hazardous cargo, such as a 20% increase for chemical tankers carrying , to account for enhanced handling and risk. Environmental protocols during transit align with international standards to minimize ecological impact. Vessels must manage ballast water in compliance with the Ballast Water Management Convention, exchanging or treating it to prevent introduction, particularly for those adjusting draft to meet canal limits by discharging clean ballast. Emissions controls require adherence to MARPOL Annex VI, including the use of low- fuel (global cap of 0.5% since 2020), with the SCA prohibiting discharge of wash water from open-loop exhaust gas cleaning systems () during transit to protect the canal's sensitive .

Challenges and Incidents

Navigation in the Suez Canal presents several inherent hazards for Suezmax vessels, which are designed to maximize dimensions within the canal's constraints but remain vulnerable to environmental factors. Strong tidal currents, particularly in the northern sector where peak speeds can reach 1.6 knots, can be exacerbated by , potentially doubling in intensity and complicating vessel control during transits. from desert sands leads to periodic formation of temporary sandbars and shoaling, necessitating ongoing to maintain navigable depths, though unexpected buildup can still pose grounding risks. Additionally, crosswinds pose challenges for vessels, though standard Suezmax designs (up to 50 meters ) are less affected than wider ships; restrictions apply to beams exceeding 64 meters (210 feet) when winds surpass 10 knots. Notable incidents underscore these vulnerabilities and their broader impacts on Suezmax operations. In July 2018, the Suezmax tanker (159,000 dwt) grounded in the canal shortly before a multi-vessel collision involving five ships, temporarily halting and highlighting engine or failures amid narrow passages. The most disruptive event was the March 2021 grounding of the larger container ship , which blocked the canal for six days, delaying over 400 vessels including numerous Suezmax tankers and causing scheduling backlogs that extended weeks for oil and bulk carriers rerouted around . More recently, in August 2023, an LNG carrier and a product tanker collided in a single-lane section, briefly suspending northbound and illustrating persistent collision risks in systems. In October 2025, the tanker Solemn (approx. 110,000 DWT) grounded at kilometer 47 while carrying Russian oil, blocking the canal and requiring tug assistance to refloat, further emphasizing grounding risks amid geopolitical tensions. In response to these events, particularly the 2021 blockage, the Suez Canal Authority has implemented mitigation measures to enhance safety and resilience. Enhanced dredging operations have been prioritized, with accelerated expansion projects—including new parallel channels—completed by early 2025 to reduce single-lane vulnerabilities and improve traffic flow for large vessels like Suezmax. Satellite-based AIS monitoring has been integrated more robustly for real-time traffic anomaly detection, allowing quicker identification of potential groundings or deviations, as demonstrated in post-incident analyses. Climate change introduces long-term challenges that could further complicate Suezmax transits. Rising sea levels, projected to increase by 0.28 to 0.98 meters globally by 2100, may alter gradients and effective limits in the by 2030, potentially reducing allowable depths for laden vessels due to denser or increased at entrances. This could necessitate adaptive or dimensional restrictions, impacting the economic viability of Suezmax designs optimized for current parameters.

Economic and Strategic Role

Impact on Global Trade

Suezmax vessels play a pivotal role in facilitating efficient international commerce by optimizing key maritime routes, particularly through the , which shortens voyages between and by approximately 40% compared to the alternative route. This time and distance savings enable faster delivery of commodities, reducing operational costs and enhancing reliability for global traders. As the largest tankers capable of laden transit through the canal, Suezmax vessels are essential for transporting crude oil and petroleum products, accounting for a significant share of the canal's oil flows, which represented about 11% of total global seaborne oil trade in 2023 but fell to approximately 6% by late 2024 due to disruptions, with overall canal tonnage 70% below 2023 levels as of May 2025 (though potential recovery may follow the November 2025 Houthi pause). The global fleet of active Suezmax tankers exceeds 500 vessels as of 2025, providing robust capacity that supports by ensuring steady flows of oil from major producing regions like the to consuming markets in and beyond. This fleet size allows for diversified routing options and resilience against disruptions, maintaining the availability of vital energy supplies amid fluctuating demand. By enabling direct canal passages that larger VLCCs cannot undertake without offloading, Suezmax operations contribute to streamlined and reduced environmental footprint from shorter voyages. Freight rates for Suezmax vessels are heavily influenced by Suez Canal tolls, which have seen periodic increases—such as a 15% hike in 2023—and discounts aimed at encouraging traffic recovery. Geopolitical tensions, including the disruptions from Houthi attacks in 2024-2025, drove rate volatility by forcing rerouting around , elevating costs and premiums that are passed onto shippers; however, the announced a pause in attacks on commercial vessels on November 11, 2025, which may allow traffic recovery and stabilize rates. These dynamics underscore the sensitivity of Suezmax economics to regional stability, with rates surging up to 41% year-on-year in some periods due to constrained capacity. In response to growing imperatives, the industry is shifting toward LNG-fueled Suezmax vessels, which can reduce by 14% to 23% on a well-to-wake basis compared to traditional operations. Recent orders, such as AET's 2025 contracts for dual-fuel Suezmax tankers, reflect this trend, aligning with global decarbonization goals while preserving the class's trade efficiency. This evolution not only mitigates environmental impacts but also positions Suezmax fleets to meet stricter international regulations, ensuring their continued relevance in sustainable global trade.

Comparisons to Other Ship Classes

Suezmax vessels, typically ranging from 120,000 to 200,000 deadweight tons (DWT), represent a larger class than tankers, which are sized between 80,000 and 120,000 DWT and are primarily deployed on shorter regional routes, such as intra-Mediterranean or West Africa-to-Europe voyages. This size differential allows Suezmax ships to achieve greater by transporting larger volumes of crude oil or cargoes over extended distances, reducing per-unit shipping costs compared to the more versatile but capacity-limited Aframax class. For instance, while an Aframax can carry approximately 750,000 barrels of oil, a Suezmax can handle up to 1.5 million barrels, optimizing efficiency for transcontinental trades without sacrificing canal transit capability. In contrast to Very Large Crude Carriers (VLCCs), which exceed 200,000 DWT and often surpass 300,000 DWT, Suezmax vessels are constrained to dimensions that permit passage through the , including a maximum of 50 meters and of around 285 meters. VLCCs, unable to navigate the canal due to their greater draft and , must typically route around the , adding significant time and fuel costs to voyages between the and or the . This positions Suezmax as an optimal balance for operators seeking high-capacity transport—offering akin to VLCCs but with the flexibility of direct Suez access, which shortens transit times by up to two weeks on key routes. Compared to Panamax vessels, designed for the with a narrower limit of approximately 32.3 and capacities generally under DWT for bulk carriers, Suezmax ships provide substantially higher for longer-haul operations, such as Asia-to-Europe oil trades. The broader and deeper draft of Suezmax (up to 20.1 ) enable greater cargo volumes, making them preferable for deep-sea bulk movements where constraints would limit efficiency, though remains suited for inter-American or grain export routes with shallower port access. The 2015 expansion of the , which added a parallel channel and increased overall capacity, along with the 2016 widening to accommodate New Panamax vessels (up to 49-meter beam and 120,000 DWT for containers), has somewhat blurred traditional size distinctions by allowing larger ships to transit both waterways more readily. However, Suezmax retains its niche relevance for oil and dry bulk trades, as the expansions have boosted overall traffic—Suez transits rose by about 10% post-2015—without fully displacing the class, which continues to offer cost-effective scale for routes avoiding the longer alternative.

References

  1. [1]
    Knowledge Centre - Kuwait Oil Tanker Co. S.A.K.
    Suezmax is a naval architecture term for the largest ship measurements capable of transiting the Suez Canal in a laden condition, and is almost exclusively used ...Missing: definition | Show results with:definition
  2. [2]
    SCA - Canal Characteristics - Suez Canal Authority
    Its depth was about 8 meters, its water are was 304 m 2 and the largest ship load that can pass through was 5000 tons, which was typical for ships sizes in ...
  3. [3]
    The Ultimate Guide to Ship Sizes - Marine Insight
    Feb 1, 2021 · A typical Suezmax vessel has a capacity of 120,000 to 200,000 DWT with a maximum 20.1 drafts with a beam no wider than 50.0 m (164.0 ft) or 12.2 ...
  4. [4]
    A guide to bulk vessel sizes - Clarksons
    Suezmax · Length: 275 metres (902 feet) · Width: 50 metres (164 feet) · Draft: 17 metres (55 feet) · Capacity: 160,000 dwt.
  5. [5]
    Tanker Sizes and Classes - Port Economics, Management and Policy
    Suezmax, 285 m, 45 m, 23 m, Between 125,000 and 180,000 dwt, originally the maximum capacity of the Suez Canal. ; VLCC, 330 m, 55 m, 28 m, Very Large Crude ...
  6. [6]
    Suez Canal | History, Map, Importance, Length, Depth, & Facts
    Oct 21, 2025 · When first opened in 1869, the canal consisted of a channel barely 8 metres (26 feet) deep, 22 metres (72 feet) wide at the bottom, and 61 to 91 ...
  7. [7]
    Suez Canal Project | Invention & Technology Magazine
    At its opening, the Canal was 164 km long, had a water depth of 7.5 m, and could handle a maximum tonnage of 5,000 D.W.T. Over the years it has been ...<|separator|>
  8. [8]
    Development of the Suez Canal, 1869-2015
    Development of the Suez Canal, 1869-2015 ; Overall Length (km), 164, 175 ; Width at 11m Depth (meters), 44, 60 ; Maximum Draft (feet), 22, 35 ; Doubled Parts (km) ...
  9. [9]
    Suez: The Reopening - Saudi Aramco World
    ... Canal to Ismailia in a five-hour voyage marking the official reopening of the Canal exactly eight years after its closure during the 1967 Arab-Israeli war.
  10. [10]
    A lifeline under threat: Why the Suez Canal's security matters for the ...
    Mar 20, 2025 · The Suez Canal is both a maritime choke point and a vital waterway for global trade and energy security.
  11. [11]
    New Suez Canal - SCA
    Achieve direct unstopped transit for 45 ships in the two directions, and stepping up the permissible draft to 66ft all through the Suez Canal;. Increase the ...Missing: current | Show results with:current
  12. [12]
    Suez Canal Expansion Opened With Pomp And Ceremony - NPR
    Aug 6, 2015 · With a depth of 24 meters (79 feet), the canal now allows the simultaneous passage of ships with up to 66 ft. draught." Merrit Kennedy, ...
  13. [13]
    Egypt launches Suez Canal expansion - BBC News
    Aug 6, 2015 · Egypt has opened a major expansion of the Suez Canal, which deepens the main waterway and provides ships with a 35km (22 mile) channel parallel to it.<|separator|>
  14. [14]
    Egypt unveils new Suez Canal navigation charts for expanded route
    Feb 3, 2025 · It increases the canal's depth from 66 feet to 72 feet and extends the dual-lane section from 72 to 82 kilometres, improving maritime efficiency ...
  15. [15]
    Egypt completes trial run of new Suez Canal channel extension
    Dec 28, 2024 · "This expansion will boost the canal's capacity by an additional 6 to 8 ships daily and enhance its ability to handle potential emergencies," ...Missing: improvements depth
  16. [16]
    https://en.amwalalghad.com/egypts-suez-canal-raises-navigation-safety-by-28-with-dual-lane-expansion-sca/
  17. [17]
    Suez Canal gains 10-km stretch, tested expansion to be operational ...
    Jan 22, 2025 · According to the Suez Canal Authority, the latest expansion extends the total length of the canal's two-way section to 82 km from a previous 72 ...Missing: 2023-2025 depth<|control11|><|separator|>
  18. [18]
    Vessel Size Groups - Cult of Sea
    Once it reopened in 1975, the Suezmax capacity went to 150,000 dwt. The Suez Canal can now accommodate all mammoth tankers in service on their ballast trips ...
  19. [19]
    Vessel Size Groups | The Geography of Transport Systems
    Once it reopened in 1975, the Suezmax capacity went to 150,000 dwt. An enlargement to enable the canal to accommodate 200,000 dwt tankers is being considered.Missing: history | Show results with:history
  20. [20]
    Ocean Transport: Vessel Classifcations - AtoZ World Business
    This standard has evolved over time. Prior to 1967, a Suezmax was a maximum of 80,000 dwt. The canal was closed between 1967 and 1975 because of the Israel ...Missing: history | Show results with:history
  21. [21]
    Panama Canal expansion will allow transit of larger ships with ... - EIA
    Sep 17, 2014 · The current Suezmax limitation on vessels passing through the Suez is a draft of 66 feet and a width of 164 feet. A ship of this size has a ...Missing: dimensions | Show results with:dimensions
  22. [22]
    Tanker top 10: the Suezmax sector - Riviera Maritime Media
    Oct 4, 2023 · The Suezmax sector covers tankers carrying crude oil in the size range between 125,000 dwt to 200,000 dwt. There are 639 live Aframax tankers ...
  23. [23]
    Suezmax Tankers Market Research Report 2033
    Suezmax tankers, with their optimal size for traversing the Suez Canal fully loaded, play a pivotal role in connecting oil producers in the Middle East and ...Suezmax Tankers Market... · Vessel Type Analysis · Competitor Outlook
  24. [24]
    Construction Requirements for Oil Tankers - Double Hulls
    In 1992 MARPOL was amended to make it mandatory for tankers of 5,000 dwt and more ordered after 6 July 1993 to be fitted with double hulls, ...Missing: Suezmax features
  25. [25]
    Understanding Design Of Oil Tanker Ships - Marine Insight
    Sep 14, 2021 · Suezmax Tanker: 1,20,000 to 2,00,000 tons DWT. VLCC (Very Large ... The classification of oil tankers based on type of cargo is not a clear and ...General Arrangement · Structural Design · Small Coastal / Single Hull...
  26. [26]
    Vessel Size Classification | TankerTrackers.com, Inc.
    Vessel Size Classification ; Suezmax, 120,000, 200,000, ~1,000,000 barrels ; VLCC, 200,000, 320,000, ~2,000,000 barrels.
  27. [27]
    Flexible trading emphasised on Suezmax design
    The vessel has a maximum loading rate of 12,000 m3/h, and a maximum loading rate through each segregation of 4,000 m3/h and in each tank 2,000 m3/h. The maximum ...<|separator|>
  28. [28]
    Sonangol's Suezmax tanker named at Hyundai Samho
    Apr 10, 2023 · Hyundai Samho Shipyard hosted a naming ceremony today for Sonangol Kulumbimbi, a Suezmax tanker built for Sonangol Shipping Holding Limited.
  29. [29]
    Bulk Carriers Explained: Types, Uses & Why They Matter - OUCO
    Jul 29, 2025 · Bulk cargo such as iron ore, coal, and grain is typically loaded using ship loaders, conveyor belts, spouts, or chutes. These systems deliver ...
  30. [30]
    Bulk Carrier Ships: Top 14 Facts Everything You Need to Know About
    Jan 12, 2024 · 7. Suezmax Bulk Carrier Ships · Dead weight tonnage of these vessels is between 120,000 to 200,000. · They usually have 9 cargo holds.
  31. [31]
    Types of container ships used in the maritime industry
    May 19, 2023 · (iii) Suezmax– The container ship has a capacity of 12000 TEU and can fit through the Suez Canal. It is smaller as compared to Panamax ships in ...Missing: examples height beam
  32. [32]
    Suez Canal limitations for container ships - SAFETY4SEA
    Oct 29, 2014 · A Suezmax tanker has a draft of 21.1 m and a beam of 50 m, producing a bounding box of 1,005 m2. Liquids are heavy cargo and draft is therefore ...
  33. [33]
    [PDF] Suez-Canal-Authority-Rules-of-Navigation.pdf
    MAXIMUM DIMENSIONS. (1). VESSEL'S SIZES AND DRAUGHTS. Art., 52 - Dimensions of Vessels Authorized to Transit: These dimensions are given hereunder:.Missing: Suezmax | Show results with:Suezmax
  34. [34]
    What are Container Ships - History, Types And Design - Marine Insight
    Jun 12, 2022 · Suezmax vessels have a carrying capacity of around 12000 TEUs, with a Breadth of about 50-57 m and draught between 14.4m-16.4m. Post-Suezmax.
  35. [35]
    An efficient single-screw, 11,000 TEU, containership: The Suez Max ...
    Aug 6, 2025 · The Suez Max SS utilizes its economies of scale and the advantages of a two-port schedule that allow it to be such a cost-efficient design.
  36. [36]
    SCA - Navigation System - Suez Canal Authority
    Southbound Convoy: The limit time is hr 2300 for the southbound convoy. ... Northbound Convoy: The limit time is hr 2300 for ships that are allowed to join the ...
  37. [37]
    Transit Guide - SANMAR SHIPPING S.A.
    Suez Canal Authority Requires Five Days Arrival Notice of Vessel's ETA for Transit. ... The Suez Canal Authority's Regulations stated that: At Least 6 ...
  38. [38]
    Tolls Table - Suez Canal Authority
    ​​New Transit Dues rates to be applied from January 15st, 2024. Vessel Type, SC Net TonnageSDR / SCNT. First 5000, Next 5000, Next 10000, Next 20000, Next 30000 ...
  39. [39]
    Suez Canal Authority Bans Scrubber Wash Water Discharge
    Jan 15, 2020 · The Suez Canal Authority has advised shipowners that discharging wash water from open-loop scrubbers during transit in the waterway is strictly forbidden.
  40. [40]
    Collision chaos in the Suez Canal - TradeWinds
    Jul 16, 2018 · Details have emerged about a multi-ship collision that took place in the Suez Canal on Sunday that lead to its temporary closure.
  41. [41]
    Two tankers collided in Egypt's Suez Canal, briefly disrupting traffic ...
    Aug 23, 2023 · Two tankers carrying oil products and liquefied natural gas collided in a single-lane stretch of the Suez Canal, briefly disrupting traffic through the global ...Missing: Suezmax | Show results with:Suezmax
  42. [42]
    EXCLUSIVE: SCA completes trial run of new Suez Canal extension
    Jan 9, 2025 · Following the 2021 grounding of the container vessel Ever Given that blocked the vital waterway for 6 days, Egypt accelerated plans to ...
  43. [43]
    Detection of maritime traffic anomalies using Satellite-AIS and ...
    Aug 15, 2022 · After entering the canal, Ever Given increased its speed to 11.2 kts at 05:21:25UTC and then increased it further to 12.6 kts at 05:24:16UTC ...
  44. [44]
    [PDF] High seas: Enabling a climate resilient Suez Canal - Marsh McLennan
    18 If there is an increasing incidence of extreme heat and sandstorm events, visibility levels for navigating through the Suez Canal will be affected, which ...Missing: sandbars Suezmax
  45. [45]
    Geotechnical modelling of the climate change impact on world ...
    Jun 17, 2021 · The United Nations' Intergovernmental Panel on Climate Change has warned that global sea levels could rise by 0.28 to 0.98 m (1–3 feet) by 2100, ...Missing: limits | Show results with:limits
  46. [46]
    Comparison of two voyage options: Suez Canal route and Cape of ...
    In contrast, the Cape of Good Hope route results in higher damage rates, with 13 % for Europe and 5 % for America (Essallamy, Bari, and Kotb 2020). Similar ...
  47. [47]
    World Oil Transit Chokepoints - EIA
    Between December 2023 and February 2024, at least 444,000 b/d of crude oil from the Middle East, mostly Iraq, and at least 455,000 b/d of oil products from ...
  48. [48]
    Suezmax Oil Tanker in Emerging Markets: Analysis and Projections ...
    Rating 4.8 (1,980) Oct 29, 2025 · These vessels typically have a deadweight tonnage (DWT) ranging from ... Economies of Scale: The Suezmax DWT range (120,000-200,000 DWT) ...
  49. [49]
    Suez Canal to hike transit tolls in 2023 - Seatrade Maritime
    Tolls for vessels using the Suez Canal are set to rise by 15% next year with the exception of dry cargo and cruise ships which will increase by 10%.
  50. [50]
    Red Sea attacks increase shipping times and freight rates - EIA
    Feb 1, 2024 · Clean petroleum product tanker rates for routes that cross the Bab el-Mandeb Strait and Suez Canal increased in December 2023 because of the ...Missing: influenced tolls
  51. [51]
    Crude tanker shares hit 2025 highs as VLCC and suezmax rates rise
    Aug 25, 2025 · Crude tanker shares hit 2025 highs as VLCC and suezmax rates rise. Baltic Exchange VLCC TCE index is at $47,334 per day, up 41% year on year; ...
  52. [52]
    https://www.kpler.com/blog/update-on-red-sea-trade-flow-impacts
  53. [53]
    https://www.marketreportanalytics.com/reports/suezmax-oil-tanker-136789
  54. [54]
    Bulk Ship Classes - Port Economics, Management and Policy
    Suezmax vessels with a capacity of between 100,000 and 160,000 dwt typically found on routes to and from West Africa and in the Mediterranean. Aframax vessels ...Missing: history | Show results with:history<|control11|><|separator|>
  55. [55]
    very large crude carrier | oil & gas logistics
    Jul 9, 2013 · Suezmax tankers offer the relative economies of scale that can be achieved with VLCCs; however, their slightly smaller size offers increased ...
  56. [56]
    A Deep Look at Oil Tankers and the Suez Canal in the Wake of the ...
    Feb 7, 2011 · This is mainly based on draft, or the depth of the tanker underwater, which has to be less than the 66 ft depth of the Canal, but there is also ...Missing: history | Show results with:history<|separator|>
  57. [57]
    vlcc | oil & gas logistics
    Suezmax tankers offer the relative economies of scale that can be achieved with VLCCs; however, their slightly smaller size offers increased versatility and ...Missing: comparison | Show results with:comparison
  58. [58]
    Various bulk carrier sizes and employment guide
    'Handysize' are the medium bulk carriers of between 24000 ~ 35000 DWT ( 130 - 150 m length & 10m draft ). They can carry cargoes to a large number of ports, may ...
  59. [59]
    What are Aframax, Panamax and Suezmax ship classes? - Quora
    Mar 29, 2016 · SUEZMAX: Before its closure in 1967 the Suez Canal could only cope with 80,000 tonne deadweight tankers and the maximum draft available was ...
  60. [60]
    Analysing Panama, Suez, and post-panamax dimensions and their ...
    Apr 1, 2025 · The term "Suezmax" describes the largest ship size that can transit the canal under normal conditions, constrained primarily by a draft limit of ...
  61. [61]
    The Economic Impacts of the New Suez Canal - IEMed
    Therefore, the new project is expected to increase Egypt's national income through the increase of current Suez Canal revenues by 259% to about $US 13.226 ...<|control11|><|separator|>
  62. [62]
    [PDF] The Suez Canal after the expansion
    It increased significantly after 2015. (Suez Canal expansion), from 61.5 to 70.3. The linear trend shows 1.5 points more every year in Egypt's LSCI. Based on ...
  63. [63]
    The Panama canal expansion: they dug it, will they come?
    Jun 22, 2016 · For example, the Suez Canal Authority is introducing discounts of up to 65% on canal transit tariffs to face increased competition from the Cape ...