• Structural, regulatory, and human errors contributed to Washington bridge collapse

    When an important bridge collapsed on Interstate 5 near Mount Vernon, Washington, in 2013, questions were raised about how such a catastrophic failure could occur. A new analysis outlines the many factors that led to the collapse, as well as steps that transportation departments can take to prevent such accidents on other bridges of similar design.

  • Building indestructible bridges

    A design process called “form-finding,” inspired by the natural world, could make possible a new generation of indestructible bridges. Form-finding enables the design of rigid structures that follow a strong natural form — structures which are sustained by a force of pure compression or tension, with no bending stresses, which are the main points of weakness in other structures.

  • Giant foam blocks keep approach slabs of bridges from settling

    The majority of the world’s largest cities, often built in areas near water bodies, have soft and compressible soils. For example, a good number of the 52,000 bridges in Texas have bump problems on entry due to settling of the soil under the pavement slabs. A research team at the University of Texas at Arlington (UTA) is using giant lightweight geofoam blocks to bolster the earth beneath roads and bridges and slow down the settling of roadways and bridges.

  • Using shotcrete to make tunnels withstand terrorist attacks

    Conflagrations and terrorist attacks are a threat for tunnels and bridges, so engineers are searching for ways to make tunnels and bridges as robust as possible. Construction materials, such as special types of high-performance concrete, which can partly absorb the impact of explosions, already exist, but due to their manufacturing principle, they cannot be made in any other shape than the slab, which cannot be used for cladding surfaces with complex geometries. A new type of shotcrete — which used to be considered impossible to manufacture — was created by scientists to render the structures more robust. Despite its high steel and synthetic-fiber contents, it can be sprayed on easily.

  • Disaster and recovery: The unexpected shall come to be expected

    In the days following the Nepal earthquake, the media has been focusing on the heart-wrenching human interest and hero-tragedy stories, but what must be emphasized is that this disaster was anticipated. More importantly, we now have the tools and building technologies to mitigate the impact of even major earthquakes. The frequency of earthquakes has not changed over the past few million years, but now millions of people live in vulnerable situations. The unexpected must come to be expected. Much-needed humanitarian assistance must transition into long-term development efforts. Simply put, instilling a culture of disaster risk reduction, investing in hazard mitigation, building as best as we can, and retrofitting what remains, will save lives.

  • Resilient rivers respond quickly to dam removal

    More than 1,000 dams have been removed across the United States because of safety concerns, sediment buildup, inefficiency, or having otherwise outlived usefulness. A paper published the other day finds that rivers are resilient and respond relatively quickly after a dam is removed. Studies show that most river channels stabilize within months or years, not decades, particularly when dams are removed rapidly.

  • Over 61,000 U.S. bridges need structural repair

    An analysis of the recently released 2014 U.S. Department of Transportation (U.S. DOT) National Bridge Inventory database finds good news and bad news when it comes to the most heavily traveled U.S. bridges. The good news is that there are over 2,000 fewer structurally deficient structures than there were in 2013. The bad news is that it means more than 61,000 structurally deficient bridges are still in need of significant repair. Cars, trucks, and school buses cross the nation’s 61,064 structurally compromised bridges 215 million times every day.

  • Bridge repair method cuts amount of time, money for bridge maintenance

    According to American Society of Civil Engineers (ASCE) 2013 Report Card for America’s Infrastructure, one in nine of the U.S. 607,380 bridges is rated as structurally deficient, and $76 billion is needed to address the issue. The high cost is partly due to the fact that traditional repair methods are time consuming and labor intensive. Researchers, however, say that they have validated a new approach that could significantly reduce the amount of time and money needed to repair bridge components damaged by corrosion: Applying ultrahigh-performance concrete to the ends of corroded bridge beams could restore bearing capacity in a fraction of the time possible with traditional repair techniques.

  • U.K. coastal railways at increasing risk from climate change

    Footage of a railway line suspended in mid-air and buffeted remorselessly by the storm that had caused the sea wall to collapse beneath it made for one of the defining images of 2014. Scenes such as those witnessed at Dawlish in Devon are set to become more frequent as a result of climate change, and the U.K. government and rail companies must face up to difficult funding decisions if rural areas currently served by coastal lines are to continue to be connected to the rail network. For railway builders in the mid-nineteenth century the coast was cheaper, flatter, and easier than using inland sites, one expert points out. “We wouldn’t have built these railway lines where they are if we had today’s knowledge.”

  • Damage-sensing, self-repairing concrete

    Skin is renewable and self-repairing — our first line of defense against the wear and tear of everyday life. If damaged, a myriad of repair processes spring into action to protect and heal the body. Clotting factors seal the break, a scab forms to protect the wound from infection, and healing agents begin to generate new tissue. Taking inspiration from this remarkable living healthcare package, researchers are asking whether damage sensing and repair can be engineered into a quite different material: concrete. Their aim is to produce a “material for life,” one with an in-built first-aid system that responds to all manner of physical and chemical damage by self-repairing, over and over again.

  • Drones to help assess post-disaster infrastructure damage

    Drones can be used for a number of applications including civilian and military purposes. Monitoring and surveillance are two of the biggest uses for drones. Now, researchers are utilizing similar technology to develop an operational prototype that will use innovative remote sensing approaches and cameras mounted on low cost aircraft or unmanned drones to detect and map fine scale transportation infrastructure damage such as cracks, deformations, and shifts immediately following natural disasters such as earthquakes, floods and hurricanes. The researchers hope the technology becomes the new, Department of Transportation approach to monitoring infrastructure after natural disasters.

  • Concrete solutions to aging, structurally deficient bridges

    According to the Pennsylvania Department of Transportation (PennDOT), the state leads the nation in the number of bridges classified as “structurally deficient.” This is probably not a surprise to most residents who have done any driving throughout the commonwealth. The state’s more than 25,000 state-owned bridges are aging — their average age is over fifty years — and in need of repair. Penn State civil engineering faculty are researching methods for enhancing the maintenance and durability of civil infrastructure — including anything made of concrete, from bridges to roads to buildings.

  • Wireless sensors keep public infrastructure safe

    European researchers have developed a wireless sensor system to monitor the safety of large infrastructure such as bridges – but also historic monuments. The new system will potentially save lives as the structure ages, and it will reducing construction cost of new infrastructure.

  • Engineers develop world’s longest “flat pack” arch bridge

    Civil Engineers at Queen’s University Belfast in collaboration with pre-cast concrete specialists Macrete Ireland have developed the world’s longest “flat pack” arch bridge. Based on the FlexiArch system, the bridge is unique in that it will be transported to site in flat-pack form but when lifted, will transform under gravity into an arch. A FlexiArch bridge requires little maintenance and should last 300 years, compared to the projected lifespan of up to 120 years that accompanies a conventional bridge.

  • Micro-capsules and bacteria used in self-healing concrete

    Researchers are aiming to develop a novel self-healing concrete that uses an inbuilt immune system to close its own wounds and prevent deterioration. Self-healing concrete could vastly increase the life of concrete structures, and would remove the need for repairs, reducing the lifetime cost of a structure by up to 50 percent. Over seven per cent of the world’s CO2 emissions are caused by cement production, so reducing the amount required by extending the lifetime of structures and removing the need for repairs will have a significant environmental impact.