Covered wagon
From Wikipedia, the free encyclopedia
This article is about the American Wild West wagon. For the railway wagon, see Covered goods wagon. For the literary journal, see Prairie Schooner (magazine).
The covered wagon, also known as a Prairie schooner, is an icon of the American Old West.
Although covered wagons were commonly used for shorter moves within the United States, in the mid-nineteenth century thousands of Americans took them across the Great Plains to Oregon and California. Overland immigrants typically used farm wagons, fitting them with five or six wooden bows that arched from side to side across the wagon bed, then stretching canvas or some other sturdy cloth over the bows, creating the cylindrical cover. Sometimes, these wagons would be as long as 15 feet.
Covered wagons were primarily used to transport goods. Small children, the elderly, and the sick or injured rode in them, but since the wagons had no suspension and the roads were rough, many people preferred to walk, unless they had horses to ride.
While covered wagons traveling short distances on good roads could be drawn by horses, those crossing the plains were usually drawn by a team of two or more pairs of oxen. These were driven by a teamster or drover, who walked at the left side of the team and directed the oxen with verbal commands and whipcracks. Mules were also used; they were harnessed and driven by someone sitting in the wagon seat holding the reins.
One covered wagon generally represented five people. A well-to-do family might have two or three wagons, or a group of single men traveling together might share a wagon. While crossing the plains, emigrants banded together to form wagon trains for mutual assistance and occasionally defense. The covered wagons and wagon trains were retired late before the era of cars and planes.
Prairie schooner is a fanciful name for the covered wagon; the white canvas covers of the wagons crossing the prairies reminded some writers of the sails of a ship at sea.[1]
[edit]
Flatcar
From Wikipedia, the free encyclopediaA flatcar (US) (also flat car (US) or flat wagon (non-US)) is a piece of railroad (US) or railway (non-US) rolling stock that consists of an open, flat deck on four or six wheels or a pair of trucks (US) or bogies (UK). The deck of the car can be wood or steel, and the sides of the deck can include pockets for stakes or tie-down points to secure loads. Flatcars designed for carrying machinery have sliding chain assemblies recessed in the deck.Flatcars are used for loads that are too large or cumbersome to load in enclosed cars such as boxcars. They are also often used to transportintermodal containers (shipping containers) or trailers as part of intermodal freight transport shipping.
Aircraft parts flatcars
Aircraft parts were hauled via conventional freight cars beginning in World War II. However, given the ever-increasing size of aircraft assemblies, the "Sky Box" method of shipping parts was developed in the late 1960s specifically to transport parts for the Boeing 747 and other "jumbo" jets of the time. The "Sky Box" consists of a two-piece metal shell that is placed atop a standard flatcar to support and protect wing and tail assemblies and fuselage sections in transit (originally, depressed-center or "fish belly" cars were utilized).Today, Boeing's 737 aircraft are shipped throughout the United States on special trains, including the fuselage.[edit]Bulkhead flatcars
Bulkhead flatcars are designed with sturdy end-walls (bulkheads) to prevent loads from shifting past the ends of the car. Loads typically carried are pipe, steel slabs,utility poles and lumber, though lumber is increasingly being hauled by centerbeam cars.[edit]Centerbeam flatcars
Centerbeams are specialty cars designed for carrying bundled building supplies such as dimensional lumber, wallboard, and fence posts. They are essentially bulkhead flatcars that have been reinforced by a longitudinal I-beam, often in the form of a Vierendeel truss, sometimes reinforced by diagonal members. They must be loaded symmetrically, with half of the payload on one side of the centerbeam and half on the other to avoid tipping over.[edit]Heavy capacity flatcars
Heavy capacity flatcars are cars designed to carry more than 100 short tons (90.72 t; 89.29 long tons). They often have more than the typical North American standard of four axles (one two axle truck at each end), and may have a depressed center or "fish belly" to handle excess-height loads as well as two trucks of three axles each (one at each end) or four trucks (two at each end) of two axles each, connected by span bolsters. Loads typically handled include electrical power equipment and large industrial production machinery.[edit]Circus use
Main article: Circus trainA circus train is a modern method of conveyance for circus troupes. One of the larger users of circus trains is the Ringling Bros. and Barnum & Bailey Circus(RBBB), a famous American circus formed when the Ringling Brothers Circus purchased the Barnum and Bailey Circus in 1907.[edit]Remote control use
Some companies, such as CSX Transportation, have former wood-carrying flatcars rebuilt into platforms which mount remote control equipment for use in operating locomotives. Such platforms are fitted with appropriate headlights, horns, and air brake appliances to operate in the leading position on a cut of cars (i.e. coupled ahead of the locomotive).[edit]Intermodal freight use
Further information: well carCOFC (container on flat car) cars are typically 89 feet (27.13 m) long and carry four 20-foot (6.10 m) intermodal containers or two 40-foot (12.19 m)/45-foot (13.72 m) shipping containers (the two 45-foot / 13.72 m containers are carryable due to the fact that the car is actually 92 ft (28.04 m) long, using the strike plates). With the rise of intermodal freight transport-specific cars, and given the age of most of these flats, numbers will decline over the next several years. Indeed, when the first well cars appeared, allowing double stacking, many container flats were re-built as autoracks. The few "new build" container flats are identifiable by their lack of decking, welded steel frame, and standard 89-foot length. One variant is the 50 feet (15.24 m) car (which usually carries one large container as a load); these are actually re-built old boxcars. Common reporting marks are FEC, CP, SOO and KTTX. The ATTX cars, which feature no spark grips and sides, are built for hauling dangerous goods (ammunition, flammable fluids, etc.).A TOFC (trailer on flat car, a.k.a. piggy-back) car once again, is usually an 89 ft car. In the past, these carried three 30 ft (9.14 m) trailers which are, as of 2007, almost obsolete, or one large, 53 ft (16.15 m), two 40-foot (12.19 m) or 45-foot (13.72 m) trailers. As intermodal traffic grows, these dedicated flats are in decline. Most have been modified to also carry containers. One notable type is Canadian Pacific Railway's XTRX service — dedicated five-unit flats that only carry trailers.[edit]Spine car
A center sill and side sill only car with lateral arms to support intermodal containers. No deck.[edit]Idler flatcars
In marine service, the linkspan between a ferry or barge and its dock is very weak. In order to avoid loss of cargo and/or heavy locomotives, an old flatcar (which is usually the lightest car available) is used as a bridge between the locomotive on the dock and the cars on the ferry or barge.Idler flatcars are also used in oversize freight service, as loads such as pipe often overhang the ends of most standard-sized flatcars. Empty flatcars will be placed on both ends of the loaded car. This protects the cargo ends from damage and ensures that the loaded cars don't bind, and damage the ends of adjacent cars.Often a flat car is placed directly in front of a crane ("big hook") in order to:- provide a way to remove a wrecked car from a crash site.
- provide a way to store new or removed rail from a work site.
- allow room for the crane's boom while in transit to and from a work site.
Containerization:
Containerization (or containerisation) is a system of intermodal freight transport using standard intermodal containers as prescribed by the International Organization for Standardization (ISO). These can be loaded and sealed intact onto container ships, railroad cars, cargo planes, and semi-trailer trucks.The introduction of containers resulted in vast improvements in port handling efficiency, thus lowering costs and helping lower freight charges and, in turn, boosting trade flows.[citation needed] Most goods can be shipped by container.
Contents
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[edit]History
[edit]Origins
Containerisation has its origins in early coal mining regions in England and Germany from the late 1700s on.[citation needed] [1] The global standardization of containers and container handling equipment was an important innovation in 20th century logistics.By the 1830s, railroads on several continents were carrying containers that could be transferred to other modes of transport. Originally used for shipping coal on and off barges, 'loose boxes' were used to containerize coal from the late 1780s, on places like the Bridgewater Canal. By the 1840s, iron boxes were in use as well as wooden ones. The early 1900s saw the adoption of closed container boxes designed for movement between road and rail.In the United Kingdom, several railway companies were using similar containers by the beginning of the 20th century and in the 1920s the Railway Clearing House standardised the RCH container. Five- or ten-foot-long, wooden and non-stackable, these early standard containers were a great success but the standard remained UK-specific.[citation needed]From 1926 to 1947, in the US, the Chicago North Shore and Milwaukee Railway carried motor carrier vehicles and shippers' vehicles loaded on flatcars between Milwaukee, Wisconsin and Chicago, Illinois. Beginning in 1929, Seatrain Lines carried railroad boxcars on its sea vessels to transport goods between New York and Cuba.[citation needed] In the mid-1930s, the Chicago Great Western Railway and then the New Haven Railroad began "piggy-back" service (transporting highway freight trailers on flatcars) limited to their own railroads. By 1953, the CB&Q, the Chicago and Eastern Illinoisand the Southern Pacific railroads had joined the innovation. Most cars were surplus flatcars equipped with new decks. By 1955, an additional 25 railroads had begun some form of piggy-back trailer service.In 1955, businessman (and former trucking company owner) Malcolm McLean worked with engineer Keith Tantlinger to develop the modern intermodal container. The challenge was to design a shipping container and devise a method of loading and locking them onto ships. The result was a 8 feet (2.4 m) tall by 8 ft (2.4 m) wide box in 10 ft (3.0 m) long units constructed from 25 mm (0.98 in) thick corrugated steel. The design incorporated a twist-lock mechanism atop each of the four corners, allowing the container to be easily secured and lifted using cranes. Helping McLean make the successful design, Tantlinger convinced McLean to give the patented designs to the industry; this began international standardization of shipping containers.[2]Toward the end of World War II, the United States Army used specialized containers to speed the loading and unloading of transport ships. The army used the term "transporters" to identify the containers, for shipping household goods of officers in the field. A "transporter" was a reusable container, 8.5 feet (2.6 m) long, 6.25 feet (1.91 m) wide, and 6.83 feet (2.08 m) high, made of rigid steel with a carrying capacity of 9,000 pounds. During the Korean War the transporter was evaluated for handling sensitive military equipment, and proving effective, was approved for broader use. Theft of material and damage to wooden crates, in addition to handling time, by stevedores at the Port of Busan,[citation needed] convinced the army that steel containers were needed. In 1952 the army began using the term CONEX, short for "Container Express". The first major shipment of CONEXes (containing engineering supplies and spare parts) were shipped by rail from the Columbus General Depot in Georgia to the Port of San Francisco, then by ship to Yokohama, Japan, and then to Korea, in late 1952. Shipment times were cut almost in half. By the Vietnam War the majority of supplies and materials were shipped with the CONEX. After the U.S. Department of Defense standardized an 8'×8' cross section container in multiples of 10' lengths for military use, it was rapidly adopted for shipping purposes.[3][4]These standards were adopted in the United Kingdom for containers and largely displaced wooden containers in the 1950s.[citation needed] The railways of the USSR had their own small containers.[5][edit]Purpose-built ships
Main article: Container shipThe first vessels purpose-built to carry containers began operation in Denmark in 1951. In the U.S. ships began carrying containers between Seattle and Alaska in 1951. The world's first intermodal container system used the purpose-built container ship the Clifford J. Rodgers, built in Montreal in 1955 and owned by the White Pass and Yukon Route. Its first trip carried 600 containers between North Vancouver, British Columbia and Skagway, Alaska, on November 26, 1955; in Skagway, the containers were unloaded to purpose-built railroad cars for transport north to the Yukon, in the first intermodal service using trucks, ships and railroad cars. Southbound containers were loaded by shippers in the Yukon, moved by rail, ship and truck, to their consignees, without opening. This first intermodal system operated from November 1955 for many years.The U.S. container shipping industry dates to April 26, 1956, when trucking entrepreneur Malcom McLean put 58 containers aboard a refitted tanker ship, theIdeal-X, and sailed them from Newark to Houston.[6] What was new in the USA about McLean's innovation was the idea of using large containers that were never opened in transit between shipper and consignee and that were transferable on an intermodal basis, among trucks, ships and railroad cars. McLean had initially favored the construction of "trailerships"—taking trailers from large trucks and stowing them in a ship’s cargo hold. This method of stowage, referred to as roll-on/roll-off, was not adopted because of the large waste in potential cargo space onboard the vessel, known as broken stowage. Instead, he modified his original concept into loading just the containers, not the chassis, onto the ships, hence the designation container ship or "box" ship.[7][8] (See also pantechnicon van and trolley and lift van.)[edit]Towards standards
During its first 20 years, many container sizes and corner fittings were used; there were dozens of incompatible container systems in the U.S. alone. Among the biggest operators, the Matson Navigation Company had a fleet of 24-foot (7.3 m) containers while Sea-Land Service, Inc used 35-foot (11 m) containers. The standard sizes and fitting and reinforcement norms that exist now evolved out of a series of compromises among international shipping companies, European railroads, U.S. railroads, and U.S. trucking companies. Four important ISO (International Organization for Standardization) recommendations standardized containerization globally[9]- January 1968: R-668 defined the terminology, dimensions and ratings
- July 1968: R-790 defined the identification markings
- January 1970: R-1161 made recommendations about corner fittings
- October 1970: R-1897 set out the minimum internal dimensions of general purpose freight containers
In the United States, containerization and other advances in shipping were impeded by the Interstate Commerce Commission, which was created in 1887 to keep railroads from using monopolist pricing and rate discrimination but fell victim to regulatory capture. By the 1960s, ICC approval was required before any shipper could carry different items in the same vehicle, or change rates. The United States' present fully integrated systems became possible only after the ICC's regulatory oversight was cut back (and abolished in 1995), trucking and rail were deregulated in the 1970s and maritime rates were deregulated in 1984.[10][edit]Today
Today, approximately 90% of non-bulk cargo worldwide moves by containers stacked on transport ships;[11] 26% of all containers originate from China.[12] As of 2005, some 18 million total containers make over 200 million trips per year. There are ships that can carry over 14,500 Twenty-foot equivalent units (TEU), for example the Emma Mærsk, 396 m long, launched August 2006. It has even been predicted that, at some point, container ships will be constrained in size only by the depth of the Straits of Malacca—one of the world's busiest shipping lanes—linking the Indian Ocean to the Pacific Ocean. This so-calledMalaccamax size constrains a ship to dimensions of 470 m in length and 60 m wide (1542 feet by 197 feet).[8]However, few initially foresaw the extent of the influence containerization would bring to the shipping industry. In the 1950s, Harvard University economistBenjamin Chinitz predicted that containerization would benefit New York by allowing it to ship industrial goods produced there more cheaply to the Southern United States than other areas, but did not anticipate that containerization might make it cheaper to import such goods from abroad. Most economic studies of containerization merely assumed that shipping companies would begin to replace older forms of transportation with containerization, but did not predict that the process of containerization itself would have some influence on producers and the extent of trading.[8]The widespread use of ISO standard containers has driven modifications in other freight-moving standards, gradually forcing removable truck bodies or swap bodies into the standard sizes and shapes (though without the strength needed to be stacked), and changing completely the worldwide use of freight palletsthat fit into ISO containers or into commercial vehicles.Improved cargo security is also an important benefit of containerization. The cargo is not visible to the casual viewer and thus is less likely to be stolen and the doors of the containers are generally sealed so that tampering is more evident. This has reduced the "falling off the truck" syndrome that long plagued the shipping industry.Use of the same basic sizes of containers across the globe has lessened the problems caused by incompatible rail gauge sizes in different countries. The majority of the rail networks in the world operate on a 1,435 mm (4 ft 8 1⁄2 in) gauge track known as standard gauge but many countries (such as Russia, India, Finland, and Lithuania) use broader gauges while many other countries in Africa and South America use narrower gauges on their networks. The use of container trains in all these countries makes trans-shipment between different gauge trains easier.[edit]Car shipping
Main article: Car shippingContainers have become a popular way to ship vehicles overseas. Cars can be loaded into 20 or 40 foot containers, loaded onto container ships, and shipped to most countries. Unlike roll-on/roll-offvehicle shipping, personal effects can be loaded into the container with the vehicle, allowing for easy international relocation.[edit]Container standards
[edit]ISO standard
Main article: Intermodal containerThere are five common standard lengths, 20-ft (6.1 m), 40-ft (12.2 m), 45-ft (13.7 m), 48-ft (14.6 m), and 53-ft (16.2 m). United States domestic standard containers are generally 48 ft (15 m) and 53-ft (rail and truck). Container capacity is often expressed in twenty-foot equivalent units (TEU, or sometimes teu). An equivalent unit is a measure of containerized cargo capacity equal to one standard 20 ft (length) × 8 ft (width) container. As this is an approximate measure, the height of the box is not considered, for instance the 9 ft 6 in (2.9 m) High cube and the 4-ft 3-in (1.3 m) half height 20 ft (6.1 m) containers are also called one TEU.The maximum gross mass for a 20 ft (6.1 m) dry cargo container is 24,000 kg, and for a 40-ft (including the 2.87 m (9 ft 6 in) high cube container), it is 30,480 kg. Allowing for the tare mass of the container, the maximum payload mass is therefore reduced to approximately 22,000 kg for 20 ft (6.1 m), and 27,000 kg for 40 ft (12 m) containers.[13]The original choice of 8 foot height for ISO containers was made in part to suit a large proportion of railway tunnels, though some had to be deepened. With the arrival of even taller containers, further enlargement is proving necessary.[14][edit]Air freight containers
Main article: Unit Load DeviceWhile major airlines use containers that are custom designed for their aircraft and associated ground handling equipment the IATA has created a set of standard container sizes, the LD-designation sizes are shown below:
Designation
Width (in) Height (in) Depth (in) Base (in) Max load (lb) Max load (kg) Shape LD-1 92.0 64.0 60.4 61.5 3500 ~1588 Type A LD-2 61.5 64.0 47.0 61.5 2700 ~1225 Type A LD-3 79.0 64.0 60.4 61.5 3500 ~1588 Type A LD-4 96.0 64.0 60.4 n/a 5400 ~2449 Rectangular LD-5 125.0 64.0 60.4 n/a 7000 ~3175 Rectangular LD-6 160.0 64.0 60.4 125.0 7000 ~3175 Type B LD-7 125.0 64.0 80.0 n/a 13300 ~6033 Rect. or Contoured LD-8 125.0 64.0 60.4 96.0 5400 ~2449 Type B LD-9 125.0 64.0 80.0 n/a 13300 ~6033 Rect. or Contoured LD-10 125.0 64.0 60.4 n/a 7000 ~3175 Contoured LD-11 125.0 64.0 60.4 n/a 7000 ~3175 Rectangular LD-29 186.0 64.0 88.0 125.0 13300 ~6033 Type B
LD-1, -2, -3, -4, and -8 are those most widely used, together with the rectangular M3 containers.[edit]Other container system standards
Some other container systems are:- PODS
- Haus-zu-Haus (House to house) (Germany)[citation needed]
- RACE (Australia)
- SECU (Sweden, Finland, UK)
- ARKAS[citation needed]
- Japanese railway containers (japanese) Containers used by Japan Freight Railway Company
[edit]Load securing in containers
See also: Load securingThere are many different ways and materials available to stabilize and secure cargo in containers used in all modes of transportation. Conventional load securing methods and materials such as steel banding and wood blocking and bracing have been around for decades and are still widely used. Load securing methods offer several, new and unknown options that have become available through technological advancement including polyester strapping and -lashing, synthetic webbings and Dunnage Bags, also known as air bags or inflatable bags.
[edit]Issues
[edit]Increased efficiency
Although there have been few direct correlations made between containers and job losses, there are a number of texts associating job losses at least in part with containerization. A 1998 study of post-containerization employment at United States ports found that container cargo could be moved nearly twenty times faster than pre-container break bulk.[15] The new system of shipping also allowed for freight consolidating jobs to move from the waterfront to points far inland, which also decreased the number of waterfront jobs.[edit]Additional fuel costs
Containerization increases the fuel costs of transport and reduces the capacity of the transport as the container itself must be shipped around not just the goods. For certain bulk products this makes containerization unattractive. For most goods the increased fuel costs and decreased transport efficiencies are currently more than offset by the handling savings. On railway the capacity of the container is far from its maximum weight capacity, and the weight of a railcar must be transported with not so much goods. In some areas (mostly USA and Canada) containers are double stacked, but this is usually not possible in other countries.[edit]Hazards
Containers have been used to smuggle contraband. The vast majority of containers are never subjected to scrutiny due to the large number of containers in use. In recent years there have been increased concerns that containers might be used to transport terrorists or terrorist materials into a country undetected. The U.S. government has advanced the Container Security Initiative (CSI), intended to ensure that high-risk cargo is examined or scanned, preferably at the port of departure.[edit]Empty containers
Containers are intended to be used constantly, being loaded with new cargo for a new destination soon after having emptied of previous cargo. This is not always possible, and in some cases, the cost of transporting an empty container to a place where it can be used is considered to be higher than the worth of the used container. Shipping lines and Container Leasing Companies have become expert at repositioning empty containers from areas of low or no demand, such as US West Coast, to areas of high demand such as China. However, damaged or retired containers may also be recycled in the form of shipping container architecture, or the steel content salvaged. In the summer of 2010, a world wide shortage of containers developed as shipping increased post-recession, while new container production had largely ceased.[16][edit]Loss at sea
Containers occasionally fall from the ships, usually during storms; 10,000 containers are lost at sea each year.[17] For instance, on November 30, 2006, a container washed ashore on the Outer Banks of North Carolina USA, along with thousands of bags of its cargo of Doritos Chips. Containers lost at sea do not necessarily sink, but seldom float very high out of the water, making them a shipping hazard that is difficult to detect. Freight from lost containers has provided oceanographers with unexpected opportunities to track global ocean currents, notably a cargo of Friendly Floatees.[18]In 2007 the International Chamber of Shipping and the World Shipping Council began work on a code of practice for container storage, including crew training on parametric rolling, safer stacking and marking of containers and security for above-deck cargo in heavy swell.[19][edit]Trades union challenges
Some of the biggest battles in the container revolution were waged in Washington, D.C. Intermodal shipping got a huge boost in the early 1970s when carriers won permission to quote combined rail-ocean rates. Later, non-vessel- operating common carriers won a long court battle with a Supreme Court decision against contracts that attempted to require that union labor be used for stuffing and stripping containers at off-pier locations.[20][edit]Double-stack containerization
Main article: Double-stack rail transportMost flatcars cannot carry more than one standard 40-foot (12.19 m) container, but if the rail line has been built with sufficient vertical clearance, a double-stack car can accept a container and still leave enough clearance for another container on top. This usually precludes operation of double-stacked wagons on lines with overhead electric wiring.[edit]History of double-stacking
United States/
Canada/
Mexico: Southern Pacific Railroad (SP), with Malcom McLean, came up with the idea of the first double-stack intermodal car in 1977.[7][21] SP then designed the first car with ACF Industries that same year.[22][23] At first it was slow to become an industry standard, then in 1984 American President Lines, started working with the SP and that same year, the first all "double stack" train left Los Angeles, California for South Kearny, New Jersey, under the name of "Stacktrain" rail service. Along the way the train transferred from the SP to Conrail. It saved shippers money and now accounts for almost 70 percent of intermodal freight transport shipments in the United States, in part due to the generous vertical clearances used by U.S. railroads. These lines are diesel operated with no overhead wiring.
Australia: Double stacking is also used in Australia between Adelaide, Parkes, Perth and Darwin. These are diesel only lines with no overhead wiring. Tunnels prevent extension of service to Melbourne, Sydney and Brisbane.
India: Double stacking in India is used for selected freight-only lines, on electrified lines with specially high overhead 25kV AC wiring.
China: using double stacked container trains under 25kV AC overhead lines.
[edit]Wagons
Railways have flat wagons and well cars that can hold 40' ISO containers.Narrow gauge railways of 610 mm (2 ft) gauge have smaller wagons that do not readily carry ISO containers, nor do the 30-foot (9.14 m) long and 7-foot (2.13 m) wide wagons of the 762 mm (2 ft 6 in) gauge Kalka-Shimla Railway. Wider narrow gauge railways of e.g. 914 mm (3 ft) and 1,000 mm (3 ft 3 3⁄8 in) gauge can take ISO containers, provided that the loading gauge allows it.[edit]Other uses for containers
Shipping container architecture is the use of containers as the basis for housing and other functional buildings for people, either as temporary housing or permanent, and either as a main building or as a cabin or workshop. Containers can also be used as sheds or storage areas in industry and commerce.Containers are also beginning to be used to house computer data centers, although these are normally specialized containers.[edit]Companies
[edit]Biggest ISO container companies
Top 20 container shipping companies in order of TEU capacity, 23 Jan 2011
Company TEU capacity[24] Number of ships A.P. Moller-Maersk Group 2,150,888 545 Mediterranean Shipping Company S.A. 1,638,962 414 CMA CGM 1,100,007 384 American President Lines 589,879 147 Evergreen Marine Corporation 554,725 152 Hapag-Lloyd 541,811 124 COSCO 498,437 134 CSAV 469,428 128 Hanjin Shipping 448,051 98 China Shipping Container Lines 440,236 122 NYK Line 365,034 95 Mitsui O.S.K. Lines 363,188 94 Orient Overseas Container Line 353,338 77 Hamburg Süd 338,778 109 Zim Integrated Shipping Services 322,685 96 K Line 318,193 82 Yang Ming Marine Transport Corporation 313,379 77 Hyundai Merchant Marine 271,604 52 Pacific International Lines 227,649 126 UASC 199,082 50
Flatcar
From Wikipedia, the free encyclopedia
A flatcar (US) (also flat car (US) or flat wagon (non-US)) is a piece of railroad (US) or railway (non-US) rolling stock that consists of an open, flat deck on four or six wheels or a pair of trucks (US) or bogies (UK). The deck of the car can be wood or steel, and the sides of the deck can include pockets for stakes or tie-down points to secure loads. Flatcars designed for carrying machinery have sliding chain assemblies recessed in the deck.
Flatcars are used for loads that are too large or cumbersome to load in enclosed cars such as boxcars. They are also often used to transportintermodal containers (shipping containers) or trailers as part of intermodal freight transport shipping.
Aircraft parts flatcars
Aircraft parts were hauled via conventional freight cars beginning in World War II. However, given the ever-increasing size of aircraft assemblies, the "Sky Box" method of shipping parts was developed in the late 1960s specifically to transport parts for the Boeing 747 and other "jumbo" jets of the time. The "Sky Box" consists of a two-piece metal shell that is placed atop a standard flatcar to support and protect wing and tail assemblies and fuselage sections in transit (originally, depressed-center or "fish belly" cars were utilized).
Today, Boeing's 737 aircraft are shipped throughout the United States on special trains, including the fuselage.
[edit]Bulkhead flatcars
Bulkhead flatcars are designed with sturdy end-walls (bulkheads) to prevent loads from shifting past the ends of the car. Loads typically carried are pipe, steel slabs,utility poles and lumber, though lumber is increasingly being hauled by centerbeam cars.
[edit]Centerbeam flatcars
Centerbeams are specialty cars designed for carrying bundled building supplies such as dimensional lumber, wallboard, and fence posts. They are essentially bulkhead flatcars that have been reinforced by a longitudinal I-beam, often in the form of a Vierendeel truss, sometimes reinforced by diagonal members. They must be loaded symmetrically, with half of the payload on one side of the centerbeam and half on the other to avoid tipping over.
[edit]Heavy capacity flatcars
Heavy capacity flatcars are cars designed to carry more than 100 short tons (90.72 t; 89.29 long tons). They often have more than the typical North American standard of four axles (one two axle truck at each end), and may have a depressed center or "fish belly" to handle excess-height loads as well as two trucks of three axles each (one at each end) or four trucks (two at each end) of two axles each, connected by span bolsters. Loads typically handled include electrical power equipment and large industrial production machinery.
[edit]Circus use
Main article: Circus train
A circus train is a modern method of conveyance for circus troupes. One of the larger users of circus trains is the Ringling Bros. and Barnum & Bailey Circus(RBBB), a famous American circus formed when the Ringling Brothers Circus purchased the Barnum and Bailey Circus in 1907.
[edit]Remote control use
Some companies, such as CSX Transportation, have former wood-carrying flatcars rebuilt into platforms which mount remote control equipment for use in operating locomotives. Such platforms are fitted with appropriate headlights, horns, and air brake appliances to operate in the leading position on a cut of cars (i.e. coupled ahead of the locomotive).
[edit]Intermodal freight use
Further information: well car
COFC (container on flat car) cars are typically 89 feet (27.13 m) long and carry four 20-foot (6.10 m) intermodal containers or two 40-foot (12.19 m)/45-foot (13.72 m) shipping containers (the two 45-foot / 13.72 m containers are carryable due to the fact that the car is actually 92 ft (28.04 m) long, using the strike plates). With the rise of intermodal freight transport-specific cars, and given the age of most of these flats, numbers will decline over the next several years. Indeed, when the first well cars appeared, allowing double stacking, many container flats were re-built as autoracks. The few "new build" container flats are identifiable by their lack of decking, welded steel frame, and standard 89-foot length. One variant is the 50 feet (15.24 m) car (which usually carries one large container as a load); these are actually re-built old boxcars. Common reporting marks are FEC, CP, SOO and KTTX. The ATTX cars, which feature no spark grips and sides, are built for hauling dangerous goods (ammunition, flammable fluids, etc.).
A TOFC (trailer on flat car, a.k.a. piggy-back) car once again, is usually an 89 ft car. In the past, these carried three 30 ft (9.14 m) trailers which are, as of 2007, almost obsolete, or one large, 53 ft (16.15 m), two 40-foot (12.19 m) or 45-foot (13.72 m) trailers. As intermodal traffic grows, these dedicated flats are in decline. Most have been modified to also carry containers. One notable type is Canadian Pacific Railway's XTRX service — dedicated five-unit flats that only carry trailers.
[edit]Spine car
A center sill and side sill only car with lateral arms to support intermodal containers. No deck.
[edit]Idler flatcars
In marine service, the linkspan between a ferry or barge and its dock is very weak. In order to avoid loss of cargo and/or heavy locomotives, an old flatcar (which is usually the lightest car available) is used as a bridge between the locomotive on the dock and the cars on the ferry or barge.
Idler flatcars are also used in oversize freight service, as loads such as pipe often overhang the ends of most standard-sized flatcars. Empty flatcars will be placed on both ends of the loaded car. This protects the cargo ends from damage and ensures that the loaded cars don't bind, and damage the ends of adjacent cars.
Often a flat car is placed directly in front of a crane ("big hook") in order to:
- provide a way to remove a wrecked car from a crash site.
- provide a way to store new or removed rail from a work site.
- allow room for the crane's boom while in transit to and from a work site.
Containerization:
Containerization (or containerisation) is a system of intermodal freight transport using standard intermodal containers as prescribed by the International Organization for Standardization (ISO). These can be loaded and sealed intact onto container ships, railroad cars, cargo planes, and semi-trailer trucks.
The introduction of containers resulted in vast improvements in port handling efficiency, thus lowering costs and helping lower freight charges and, in turn, boosting trade flows.[citation needed] Most goods can be shipped by container.
Contents[hide] |
[edit]History
[edit]Origins
Containerisation has its origins in early coal mining regions in England and Germany from the late 1700s on.[citation needed] [1] The global standardization of containers and container handling equipment was an important innovation in 20th century logistics.
By the 1830s, railroads on several continents were carrying containers that could be transferred to other modes of transport. Originally used for shipping coal on and off barges, 'loose boxes' were used to containerize coal from the late 1780s, on places like the Bridgewater Canal. By the 1840s, iron boxes were in use as well as wooden ones. The early 1900s saw the adoption of closed container boxes designed for movement between road and rail.
In the United Kingdom, several railway companies were using similar containers by the beginning of the 20th century and in the 1920s the Railway Clearing House standardised the RCH container. Five- or ten-foot-long, wooden and non-stackable, these early standard containers were a great success but the standard remained UK-specific.[citation needed]
From 1926 to 1947, in the US, the Chicago North Shore and Milwaukee Railway carried motor carrier vehicles and shippers' vehicles loaded on flatcars between Milwaukee, Wisconsin and Chicago, Illinois. Beginning in 1929, Seatrain Lines carried railroad boxcars on its sea vessels to transport goods between New York and Cuba.[citation needed] In the mid-1930s, the Chicago Great Western Railway and then the New Haven Railroad began "piggy-back" service (transporting highway freight trailers on flatcars) limited to their own railroads. By 1953, the CB&Q, the Chicago and Eastern Illinoisand the Southern Pacific railroads had joined the innovation. Most cars were surplus flatcars equipped with new decks. By 1955, an additional 25 railroads had begun some form of piggy-back trailer service.
In 1955, businessman (and former trucking company owner) Malcolm McLean worked with engineer Keith Tantlinger to develop the modern intermodal container. The challenge was to design a shipping container and devise a method of loading and locking them onto ships. The result was a 8 feet (2.4 m) tall by 8 ft (2.4 m) wide box in 10 ft (3.0 m) long units constructed from 25 mm (0.98 in) thick corrugated steel. The design incorporated a twist-lock mechanism atop each of the four corners, allowing the container to be easily secured and lifted using cranes. Helping McLean make the successful design, Tantlinger convinced McLean to give the patented designs to the industry; this began international standardization of shipping containers.[2]
Toward the end of World War II, the United States Army used specialized containers to speed the loading and unloading of transport ships. The army used the term "transporters" to identify the containers, for shipping household goods of officers in the field. A "transporter" was a reusable container, 8.5 feet (2.6 m) long, 6.25 feet (1.91 m) wide, and 6.83 feet (2.08 m) high, made of rigid steel with a carrying capacity of 9,000 pounds. During the Korean War the transporter was evaluated for handling sensitive military equipment, and proving effective, was approved for broader use. Theft of material and damage to wooden crates, in addition to handling time, by stevedores at the Port of Busan,[citation needed] convinced the army that steel containers were needed. In 1952 the army began using the term CONEX, short for "Container Express". The first major shipment of CONEXes (containing engineering supplies and spare parts) were shipped by rail from the Columbus General Depot in Georgia to the Port of San Francisco, then by ship to Yokohama, Japan, and then to Korea, in late 1952. Shipment times were cut almost in half. By the Vietnam War the majority of supplies and materials were shipped with the CONEX. After the U.S. Department of Defense standardized an 8'×8' cross section container in multiples of 10' lengths for military use, it was rapidly adopted for shipping purposes.[3][4]
These standards were adopted in the United Kingdom for containers and largely displaced wooden containers in the 1950s.[citation needed] The railways of the USSR had their own small containers.[5]
[edit]Purpose-built ships
Main article: Container ship
The first vessels purpose-built to carry containers began operation in Denmark in 1951. In the U.S. ships began carrying containers between Seattle and Alaska in 1951. The world's first intermodal container system used the purpose-built container ship the Clifford J. Rodgers, built in Montreal in 1955 and owned by the White Pass and Yukon Route. Its first trip carried 600 containers between North Vancouver, British Columbia and Skagway, Alaska, on November 26, 1955; in Skagway, the containers were unloaded to purpose-built railroad cars for transport north to the Yukon, in the first intermodal service using trucks, ships and railroad cars. Southbound containers were loaded by shippers in the Yukon, moved by rail, ship and truck, to their consignees, without opening. This first intermodal system operated from November 1955 for many years.
The U.S. container shipping industry dates to April 26, 1956, when trucking entrepreneur Malcom McLean put 58 containers aboard a refitted tanker ship, theIdeal-X, and sailed them from Newark to Houston.[6] What was new in the USA about McLean's innovation was the idea of using large containers that were never opened in transit between shipper and consignee and that were transferable on an intermodal basis, among trucks, ships and railroad cars. McLean had initially favored the construction of "trailerships"—taking trailers from large trucks and stowing them in a ship’s cargo hold. This method of stowage, referred to as roll-on/roll-off, was not adopted because of the large waste in potential cargo space onboard the vessel, known as broken stowage. Instead, he modified his original concept into loading just the containers, not the chassis, onto the ships, hence the designation container ship or "box" ship.[7][8] (See also pantechnicon van and trolley and lift van.)
[edit]Towards standards
During its first 20 years, many container sizes and corner fittings were used; there were dozens of incompatible container systems in the U.S. alone. Among the biggest operators, the Matson Navigation Company had a fleet of 24-foot (7.3 m) containers while Sea-Land Service, Inc used 35-foot (11 m) containers. The standard sizes and fitting and reinforcement norms that exist now evolved out of a series of compromises among international shipping companies, European railroads, U.S. railroads, and U.S. trucking companies. Four important ISO (International Organization for Standardization) recommendations standardized containerization globally[9]
- January 1968: R-668 defined the terminology, dimensions and ratings
- July 1968: R-790 defined the identification markings
- January 1970: R-1161 made recommendations about corner fittings
- October 1970: R-1897 set out the minimum internal dimensions of general purpose freight containers
In the United States, containerization and other advances in shipping were impeded by the Interstate Commerce Commission, which was created in 1887 to keep railroads from using monopolist pricing and rate discrimination but fell victim to regulatory capture. By the 1960s, ICC approval was required before any shipper could carry different items in the same vehicle, or change rates. The United States' present fully integrated systems became possible only after the ICC's regulatory oversight was cut back (and abolished in 1995), trucking and rail were deregulated in the 1970s and maritime rates were deregulated in 1984.[10]
[edit]Today
Today, approximately 90% of non-bulk cargo worldwide moves by containers stacked on transport ships;[11] 26% of all containers originate from China.[12] As of 2005, some 18 million total containers make over 200 million trips per year. There are ships that can carry over 14,500 Twenty-foot equivalent units (TEU), for example the Emma Mærsk, 396 m long, launched August 2006. It has even been predicted that, at some point, container ships will be constrained in size only by the depth of the Straits of Malacca—one of the world's busiest shipping lanes—linking the Indian Ocean to the Pacific Ocean. This so-calledMalaccamax size constrains a ship to dimensions of 470 m in length and 60 m wide (1542 feet by 197 feet).[8]
However, few initially foresaw the extent of the influence containerization would bring to the shipping industry. In the 1950s, Harvard University economistBenjamin Chinitz predicted that containerization would benefit New York by allowing it to ship industrial goods produced there more cheaply to the Southern United States than other areas, but did not anticipate that containerization might make it cheaper to import such goods from abroad. Most economic studies of containerization merely assumed that shipping companies would begin to replace older forms of transportation with containerization, but did not predict that the process of containerization itself would have some influence on producers and the extent of trading.[8]
The widespread use of ISO standard containers has driven modifications in other freight-moving standards, gradually forcing removable truck bodies or swap bodies into the standard sizes and shapes (though without the strength needed to be stacked), and changing completely the worldwide use of freight palletsthat fit into ISO containers or into commercial vehicles.
Improved cargo security is also an important benefit of containerization. The cargo is not visible to the casual viewer and thus is less likely to be stolen and the doors of the containers are generally sealed so that tampering is more evident. This has reduced the "falling off the truck" syndrome that long plagued the shipping industry.
Use of the same basic sizes of containers across the globe has lessened the problems caused by incompatible rail gauge sizes in different countries. The majority of the rail networks in the world operate on a 1,435 mm (4 ft 8 1⁄2 in) gauge track known as standard gauge but many countries (such as Russia, India, Finland, and Lithuania) use broader gauges while many other countries in Africa and South America use narrower gauges on their networks. The use of container trains in all these countries makes trans-shipment between different gauge trains easier.
[edit]Car shipping
Main article: Car shipping
Containers have become a popular way to ship vehicles overseas. Cars can be loaded into 20 or 40 foot containers, loaded onto container ships, and shipped to most countries. Unlike roll-on/roll-offvehicle shipping, personal effects can be loaded into the container with the vehicle, allowing for easy international relocation.
[edit]Container standards
[edit]ISO standard
Main article: Intermodal container
There are five common standard lengths, 20-ft (6.1 m), 40-ft (12.2 m), 45-ft (13.7 m), 48-ft (14.6 m), and 53-ft (16.2 m). United States domestic standard containers are generally 48 ft (15 m) and 53-ft (rail and truck). Container capacity is often expressed in twenty-foot equivalent units (TEU, or sometimes teu). An equivalent unit is a measure of containerized cargo capacity equal to one standard 20 ft (length) × 8 ft (width) container. As this is an approximate measure, the height of the box is not considered, for instance the 9 ft 6 in (2.9 m) High cube and the 4-ft 3-in (1.3 m) half height 20 ft (6.1 m) containers are also called one TEU.
The maximum gross mass for a 20 ft (6.1 m) dry cargo container is 24,000 kg, and for a 40-ft (including the 2.87 m (9 ft 6 in) high cube container), it is 30,480 kg. Allowing for the tare mass of the container, the maximum payload mass is therefore reduced to approximately 22,000 kg for 20 ft (6.1 m), and 27,000 kg for 40 ft (12 m) containers.[13]
The original choice of 8 foot height for ISO containers was made in part to suit a large proportion of railway tunnels, though some had to be deepened. With the arrival of even taller containers, further enlargement is proving necessary.[14]
[edit]Air freight containers
Main article: Unit Load Device
While major airlines use containers that are custom designed for their aircraft and associated ground handling equipment the IATA has created a set of standard container sizes, the LD-designation sizes are shown below:
| Designation | Width (in) | Height (in) | Depth (in) | Base (in) | Max load (lb) | Max load (kg) | Shape |
|---|---|---|---|---|---|---|---|
| LD-1 | 92.0 | 64.0 | 60.4 | 61.5 | 3500 | ~1588 | Type A |
| LD-2 | 61.5 | 64.0 | 47.0 | 61.5 | 2700 | ~1225 | Type A |
| LD-3 | 79.0 | 64.0 | 60.4 | 61.5 | 3500 | ~1588 | Type A |
| LD-4 | 96.0 | 64.0 | 60.4 | n/a | 5400 | ~2449 | Rectangular |
| LD-5 | 125.0 | 64.0 | 60.4 | n/a | 7000 | ~3175 | Rectangular |
| LD-6 | 160.0 | 64.0 | 60.4 | 125.0 | 7000 | ~3175 | Type B |
| LD-7 | 125.0 | 64.0 | 80.0 | n/a | 13300 | ~6033 | Rect. or Contoured |
| LD-8 | 125.0 | 64.0 | 60.4 | 96.0 | 5400 | ~2449 | Type B |
| LD-9 | 125.0 | 64.0 | 80.0 | n/a | 13300 | ~6033 | Rect. or Contoured |
| LD-10 | 125.0 | 64.0 | 60.4 | n/a | 7000 | ~3175 | Contoured |
| LD-11 | 125.0 | 64.0 | 60.4 | n/a | 7000 | ~3175 | Rectangular |
| LD-29 | 186.0 | 64.0 | 88.0 | 125.0 | 13300 | ~6033 | Type B |
LD-1, -2, -3, -4, and -8 are those most widely used, together with the rectangular M3 containers.
[edit]Other container system standards
Some other container systems are:
- PODS
- Haus-zu-Haus (House to house) (Germany)[citation needed]
- RACE (Australia)
- SECU (Sweden, Finland, UK)
- ARKAS[citation needed]
- Japanese railway containers (japanese) Containers used by Japan Freight Railway Company
[edit]Load securing in containers
See also: Load securing
There are many different ways and materials available to stabilize and secure cargo in containers used in all modes of transportation. Conventional load securing methods and materials such as steel banding and wood blocking and bracing have been around for decades and are still widely used. Load securing methods offer several, new and unknown options that have become available through technological advancement including polyester strapping and -lashing, synthetic webbings and Dunnage Bags, also known as air bags or inflatable bags.
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[edit]Issues
[edit]Increased efficiency
Although there have been few direct correlations made between containers and job losses, there are a number of texts associating job losses at least in part with containerization. A 1998 study of post-containerization employment at United States ports found that container cargo could be moved nearly twenty times faster than pre-container break bulk.[15] The new system of shipping also allowed for freight consolidating jobs to move from the waterfront to points far inland, which also decreased the number of waterfront jobs.
[edit]Additional fuel costs
Containerization increases the fuel costs of transport and reduces the capacity of the transport as the container itself must be shipped around not just the goods. For certain bulk products this makes containerization unattractive. For most goods the increased fuel costs and decreased transport efficiencies are currently more than offset by the handling savings. On railway the capacity of the container is far from its maximum weight capacity, and the weight of a railcar must be transported with not so much goods. In some areas (mostly USA and Canada) containers are double stacked, but this is usually not possible in other countries.
[edit]Hazards
Containers have been used to smuggle contraband. The vast majority of containers are never subjected to scrutiny due to the large number of containers in use. In recent years there have been increased concerns that containers might be used to transport terrorists or terrorist materials into a country undetected. The U.S. government has advanced the Container Security Initiative (CSI), intended to ensure that high-risk cargo is examined or scanned, preferably at the port of departure.
[edit]Empty containers
Containers are intended to be used constantly, being loaded with new cargo for a new destination soon after having emptied of previous cargo. This is not always possible, and in some cases, the cost of transporting an empty container to a place where it can be used is considered to be higher than the worth of the used container. Shipping lines and Container Leasing Companies have become expert at repositioning empty containers from areas of low or no demand, such as US West Coast, to areas of high demand such as China. However, damaged or retired containers may also be recycled in the form of shipping container architecture, or the steel content salvaged. In the summer of 2010, a world wide shortage of containers developed as shipping increased post-recession, while new container production had largely ceased.[16]
[edit]Loss at sea
Containers occasionally fall from the ships, usually during storms; 10,000 containers are lost at sea each year.[17] For instance, on November 30, 2006, a container washed ashore on the Outer Banks of North Carolina USA, along with thousands of bags of its cargo of Doritos Chips. Containers lost at sea do not necessarily sink, but seldom float very high out of the water, making them a shipping hazard that is difficult to detect. Freight from lost containers has provided oceanographers with unexpected opportunities to track global ocean currents, notably a cargo of Friendly Floatees.[18]
In 2007 the International Chamber of Shipping and the World Shipping Council began work on a code of practice for container storage, including crew training on parametric rolling, safer stacking and marking of containers and security for above-deck cargo in heavy swell.[19]
[edit]Trades union challenges
Some of the biggest battles in the container revolution were waged in Washington, D.C. Intermodal shipping got a huge boost in the early 1970s when carriers won permission to quote combined rail-ocean rates. Later, non-vessel- operating common carriers won a long court battle with a Supreme Court decision against contracts that attempted to require that union labor be used for stuffing and stripping containers at off-pier locations.[20]
[edit]Double-stack containerization
Main article: Double-stack rail transport
Most flatcars cannot carry more than one standard 40-foot (12.19 m) container, but if the rail line has been built with sufficient vertical clearance, a double-stack car can accept a container and still leave enough clearance for another container on top. This usually precludes operation of double-stacked wagons on lines with overhead electric wiring.
[edit]History of double-stacking
- United States/ Canada/ Mexico: Southern Pacific Railroad (SP), with Malcom McLean, came up with the idea of the first double-stack intermodal car in 1977.[7][21] SP then designed the first car with ACF Industries that same year.[22][23] At first it was slow to become an industry standard, then in 1984 American President Lines, started working with the SP and that same year, the first all "double stack" train left Los Angeles, California for South Kearny, New Jersey, under the name of "Stacktrain" rail service. Along the way the train transferred from the SP to Conrail. It saved shippers money and now accounts for almost 70 percent of intermodal freight transport shipments in the United States, in part due to the generous vertical clearances used by U.S. railroads. These lines are diesel operated with no overhead wiring.
- Australia: Double stacking is also used in Australia between Adelaide, Parkes, Perth and Darwin. These are diesel only lines with no overhead wiring. Tunnels prevent extension of service to Melbourne, Sydney and Brisbane.
- India: Double stacking in India is used for selected freight-only lines, on electrified lines with specially high overhead 25kV AC wiring.
- China: using double stacked container trains under 25kV AC overhead lines.
[edit]Wagons
Railways have flat wagons and well cars that can hold 40' ISO containers.
Narrow gauge railways of 610 mm (2 ft) gauge have smaller wagons that do not readily carry ISO containers, nor do the 30-foot (9.14 m) long and 7-foot (2.13 m) wide wagons of the 762 mm (2 ft 6 in) gauge Kalka-Shimla Railway. Wider narrow gauge railways of e.g. 914 mm (3 ft) and 1,000 mm (3 ft 3 3⁄8 in) gauge can take ISO containers, provided that the loading gauge allows it.
[edit]Other uses for containers
Shipping container architecture is the use of containers as the basis for housing and other functional buildings for people, either as temporary housing or permanent, and either as a main building or as a cabin or workshop. Containers can also be used as sheds or storage areas in industry and commerce.
Containers are also beginning to be used to house computer data centers, although these are normally specialized containers.
[edit]Companies
[edit]Biggest ISO container companies
| Company | TEU capacity[24] | Number of ships |
|---|---|---|
| A.P. Moller-Maersk Group | 2,150,888 | 545 |
| Mediterranean Shipping Company S.A. | 1,638,962 | 414 |
| CMA CGM | 1,100,007 | 384 |
| American President Lines | 589,879 | 147 |
| Evergreen Marine Corporation | 554,725 | 152 |
| Hapag-Lloyd | 541,811 | 124 |
| COSCO | 498,437 | 134 |
| CSAV | 469,428 | 128 |
| Hanjin Shipping | 448,051 | 98 |
| China Shipping Container Lines | 440,236 | 122 |
| NYK Line | 365,034 | 95 |
| Mitsui O.S.K. Lines | 363,188 | 94 |
| Orient Overseas Container Line | 353,338 | 77 |
| Hamburg Süd | 338,778 | 109 |
| Zim Integrated Shipping Services | 322,685 | 96 |
| K Line | 318,193 | 82 |
| Yang Ming Marine Transport Corporation | 313,379 | 77 |
| Hyundai Merchant Marine | 271,604 | 52 |
| Pacific International Lines | 227,649 | 126 |
| UASC | 199,082 | 50 |
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