A Jersey barrier, or Jersey wall, is a modular concrete or plastic barrier employed to separate lanes of traffic. It is designed to minimize vehicle damage in cases of incidental contact while still preventing vehicle crossovers resulting in a likely head-on collision. Jersey barriers are also used to reroute traffic and protect pedestrians and workers during highway construction, as well as temporary and semi-permanent protections against landborne attack such as suicide vehicle bombs. A Jersey barrier also is known as a K-rail, a term stipulated in the California Department of Transportation specification for temporary concrete traffic barriers, or colloquially, as a Jersey bump. Jersey barriers were developed in the 1950s, beginning in the U.S. state of New Jersey as separators between lanes of a highway. Over time, they grew taller and became more modular. Taller barriers have the added advantage of blocking most oncoming headlights. Now, plastic water-filled barriers of the same general shape are also called Jersey barriers.
Development and use
The Jersey barrier, also called New Jersey wall, was developed in the 1950s, at the Stevens Institute of Technology, New Jersey, United States, under the direction of the New Jersey State Highway Department to divide multiple lanes on a highway. A typical Jersey barrier stands tall and is made of steel-reinforced poured concrete or plastic. Many are constructed with the embedded steel reinforcement protruding from each end, allowing them to be incorporated into permanent emplacements when linked to one another by sections of fresh concrete poured on-site. Their widespread use in road construction has led to wide application as a generic, portable barrier during construction projects and temporary rerouting of traffic into stopgap carpool and rush-hour reversing highway lanes. Most of the original barriers constructed in New Jersey in the 1950s and early 1960s were not "modular"; they were poured in place the way curbs are. Many of the first installations were much shorter than the heights discussed here, typically about two feet tall. Some dividers on county or local roads may have been lower than that since they replaced a raised concrete rumble strip that would dissuade, but not prevent, traffic crossing from one lane to another. Even Route 46 had the rumble strip in many places before gradually, the higher barrier was installed. These lower dividers are visible in old photographs. When the Bergen Mall was first opened in Paramus, these rumble strip dividers were extensively used on the roadway that separated the grocery stores from the mall proper. The design of the Jersey barrier was specifically intended to minimize damage in incidental accidents and reduce the likelihood of a car crossing into oncoming lanes in the event of a collision. In common shallow-angle hits, sheet-metal damage is minimized by allowing the vehicle tires to ride up on the lower sloped face. Head-on vehicle collisions are minimized by gradually lifting the vehicle and pivoting it away from oncoming vehicles and back into traffic heading in its original direction. Modern variations include the constant-slope barrier and the F-shape barrier. The F-shape is generally similar to the Jersey barrier in appearance, but is taller, with somewhat different angles. The UK equivalent is the concrete step barrier. First tested in 1968 by the then Department of Highways in Ontario, Canada, the Ontario Tall Wall is a variant of the Jersey barrier. Standing at, it is taller than the standard Jersey barrier. In Ontario, the Ministry of Transportation is replacing guiderails with these barriers on 400-series highways. The New Jersey Turnpike Authority developed and tested a similar, but heavily reinforced, design. This barrier design has been credited with effectively containing and redirecting larger vehicles, including semi-trailer trucks. The states of New York, Massachusetts and New Jersey have adopted the taller barrier for their roads, as compared to the standard suggested by the Federal Highway Administration. Designs with two rectangular notches at the bottom allow for forklift-style lifting by front-end loaders. Barriers meant for short-term placement, especially in military and security barrier uses, might include steel rebar loops embedded in the top surface for rapid hook-and-cable system lifting. The 2010 G-20 Toronto summit used modified modular Jersey barriers with wired fencing bolted onto the concrete. The fence used the barrier as sturdy base to prevent protesters from toppling the fence around the security zone at the Metro Toronto Convention Centre. The U.S. military nicknamed the devices as "Qaddafi Blocks" after truck bomb attacks in Beirut in 1983 resulted in more widespread use in military installations. Sometimes they are deployed to form a chicane to slow vehicular traffic arriving at military installations or other secure areas. The Ohio Department of Transportation mandates specific design requirements for their . ODOT has marked all compliant precast concrete barrier walls with “350,” indicating that they adhere to the requirements laid out in the National Cooperative Highway Research Program's Report 350. Without this marking, a barrier wall is not approved for use in Ohio.
Plastic Jersey barriers
Hollow polyethylene barriers have been developed for short-term applications where portability is important. These plastic barriers are normally filled with water after placement on-site to provide a moderate level of crash protection, then emptied prior to removal. They are not designed to deflect vehicles, so vehicles may penetrate the barriers. These barriers can also be filled with sand at the cost of reduced portability.
A use of Jersey barriers other than for traffic control was depicted in the motion picture Volcano, where Office of Emergency Management Director Michael "Mike" Roark tries to stop a lava flow from causing further destruction of Wilshire Boulevard in Los Angeles. He orders Jersey barriers, referring to them by the California name, K-rails, to be set up double-stacked in a horseshoe shape, which, combined with flooding the dammed-up lava with water, halts the lava flow.