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Perforated steel planks for temporary runways From Wikipedia, the free encyclopedia
Marston Mat, more properly called pierced (or perforated) steel planking (PSP), is standardized, perforated steel matting material developed by the United States at the Waterways Experiment Station shortly before World War II, primarily for the rapid construction of temporary runways and landing strips (also misspelled as Marsden matting). The nickname came from Marston, North Carolina, adjacent to Camp Mackall airfield where the material was first used.[1]
Pierced (pressed, steel planking, named after the manufacturing process) steel planking consisted of steel strips with punched lightening holes in it. These holes were in rows, and a formation of U-shaped channels between the holes. Hooks were formed along one long edge and slots along the other long edge so that adjacent mats could be connected. The short edges were cut straight with no holes or hooks. To achieve lengthwise interlocking, the mats were laid in a staggered pattern.
The hooks were usually held in the slots by a steel clip that filled the part of the slot that is empty when the adjacent sheets are properly engaged. The holes were bent up at their edges so that the beveled edge stiffened the area around the hole. In some mats a T-shaped stake could be driven at intervals through the holes to keep the assembly in place on the ground. Sometimes the sheets were welded together.
A typical later PSP was the M8 landing mat. A single piece weighed about 66 pounds (30 kg) and was 10 ft (3.0 m) long by 15 in (0.38 m) wide. The hole pattern for the sheet was produced to allow easier transportation by aircraft, since it weighed about two-thirds as much. A lighter-weight aluminum plank version was developed, to ease logistics in the construction of airfields in less accessible areas. This was pierced aluminum planking, or PAP, as it was commonly known.[2] PAP was and is not as common as PSP. Aluminum was a controlled strategic material during World War II, so much less was made; it was typically able to handle only half as many loading cycles as steel, and its high scrap value and short usable life led to recycling rather than reuse.
In 1939, the United States Army Air Corps began exploring the use of runway mats for the construction of unimproved airfields. Systems for this purpose had already been tested by Britain, which used a material similar to heavy duty chicken wire, and France, using a grid of steel chevrons.[3] The design directive for what would become the Marston mat was officially assigned to the Army Corps of Engineers on December 11, 1939.[4] [3] Development of landing mats in the United States began in December 1939 at Langley Field. The responsibility for development was shifted to the Engineer Board at Fort Belvoir in May 1940.[4] Gerald G. Greulich of the Carnegie Steel Company also contributed to the design efforts. Early versions tested during the summer of 1940 were solid (non-perforated), ribbed steel. The design was modified during the winter of 1940-1941 with the distinctive punched holes seen in the production version.[3]
The first practical use of the Marston mat was during the Carolina Maneuvers, a series of United States Army exercises held in November 1941. A 3,000 feet (910 m) by 150 feet (46 m) airstrip was constructed of the material near Camp Mackall in the area of Marston, North Carolina. Installation of the airstrip was completed in 11 days. The completed airstrip was visited by General Henry H. Arnold, then Chief of the Army Air Corps, who called it “the year’s greatest achievement in aviation warfare.” The airstrip was dismantled immediately after the exercises and the component mats moved by rail to Langley Field.[3][5]
Marston Mat was extensively used during World War II by Army engineers and Seabees ("CBs"; Construction Battalions) to build runways and other readily usable surfaces over all kinds of terrain. An early in-theater use of PSP was in constructing a 5,000-foot (1,500 m) runway on Greenland's 'Bluie West One' (BW-1), an Allied Ferry Command and U.S.A.A.F airfield located on the extreme southwest corner of Greenland, at the termination of Eriksfjord, and near the coastal community of Narsarsuaq. Construction began in early fall 1941, and the first aircraft landed on Jan 24, 1942. Deemed a success, it was then used extensively in the Pacific Theater of Operations. A C-47 Skytrain supply aircraft was the first plane to land on the first steel-mat runway constructed in France after the invasion of Normandy.[6]
On Pacific islands the matting was typically covered with crushed and rolled coral or soil to form a level surface. The perforated and channeled design of the matting created strength and rigidity and facilitated drainage. A runway 200 feet (61 m) wide and 5,000 feet (1,500 m) long could be created within two days by a small team of engineers.
At the start of the Berlin Airlift the runways at Tempelhof Airport in the US Zone of Berlin were made of PSP. Designed to support fighters and smaller cargo aircraft, the Douglas C-54 Skymaster that formed the backbone of the U.S. effort was too heavy for the PSP. Berliners were hired to fix the runway between the three-minute arrivals, running onto the runways with bags of sand to dump onto the mats and soften the surface.
With the deployment of jet aircraft and helicopters, foreign object damage (FOD) became a larger hazard. In moist tropical areas, such as Vietnam, vegetation growing through the mats became an issue. Jet blast or rotor downdraft could dislodge loose material on the ground, which might be sucked into jet inlets, and vegetation required mowing or herbicides. The M8A1 mat was developed to prevent this, omitting the pierced holes that exposed the soil beneath.[7] This mat has a solid surface, strengthened by corrugations that also encouraged the drainage of rainwater. The mat size also changed to be 22 by 144 inches (560 mm × 3,660 mm).
In order to support heavier aircraft, the Corps of Engineers developed the XM-19, a square mat constructed of aluminum. This mat was a lightweight, hollow design weighing 68 pounds (31 kg). The mats included an internal aluminum honeycomb structure, which increased the carrying capacity while remaining lightweight. The outer surface of the mat was covered in an anti-skid coating.[2]
In the mid-1960s, the AM2 mat was developed, using the lightweight aluminum honeycomb core construction of the XM-19, but in a rectangular size similar to earlier mat designs. The AM2 measures 24 by 144 inches (610 mm × 3,660 mm). Versions of the AM2 are still in use with the United States military.[2]
Landing mats of all types were widely used for construction of bunker roofs and for reinforcing field fortifications, as well as service roads inside fire support bases.
Large quantities of matting were produced; approximately 2 million tons costing more than US$200 million (in the 1940s).[8] At the end of the war a large amount of the material remained as war surplus and was pressed into use in various civil engineering applications such as road and bridge construction. As they were made from steel with a high manganese content, the matting was also highly resistant to corrosion.[9] In various countries located in the Pacific Theater, particularly in the Philippines and Papua New Guinea, matting still remains in use as fencing[10] or roadway barriers, in some cases stretching for miles.
After the war, PSP was used by many southeastern U.S. auto racers (including NASCAR teams) to construct trailers. It was a readily available material for this purpose since it was manufactured in the area and could be found at many abandoned military airfields.[citation needed]
Surplus sections of Vietnam War-era mats were used to construct fences along the U.S.-Mexico border in the 1990s.[11]
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