'we cannot just accept the structure as it was built'

Baltimore Bridge Collapse: A Bridge Engineer Explains What Happened, And What Needs To Change

Bridges are getting safer — but their designers need to keep up with the ever-growing size of cargo ships.

1 month ago · 13.4k reads ·

When the container ship MV Dali, 300 metres long and massing around 100,000 tonnes, lost power and slammed into one of the support piers of the Francis Scott Key Bridge in Baltimore, the bridge collapsed in moments. Six people are presumed dead, several others injured, and the city and region are expecting a months-long logistical nightmare in the absence of a crucial transport link.

It was a shocking event, not only for the public but for bridge engineers like me. We work very hard to ensure bridges are safe, and overall the probability of being injured or worse in a bridge collapse remains even lower than the chance of being struck by lightning.

However, the images from Baltimore are a reminder that safety can’t be taken for granted. We need to remain vigilant.

So why did this bridge collapse? And, just as importantly, how might we make other bridges more safe against such collapse?

A 20th century bridge meets a 21st century ship

The Francis Scott Key Bridge was built through the mid 1970s and opened in 1977. The main structure over the navigation channel is a “continuous truss bridge” in three sections or spans.

The bridge rests on four supports, two of which sit each side of the navigable waterway. It is these two piers that are critical to protect against ship impacts.

And indeed, there were two layers of protection: a so-called “dolphin” structure made from concrete, and a fender. The dolphins are in the water about 100 metres upstream and downstream of the piers. They are intended to be sacrificed in the event of a wayward ship, absorbing its energy and being deformed in the process but keeping the ship from hitting the bridge itself.

Diagram of a bridge — Francis Scott Key Bridge in Baltimore, showing the pier struck by the cargo ship and the sections of bridge which collapsed as a result. F Vasconcellos / Wikimedia, CC BY-SA

The fender is the last layer of protection. It is a structure made of timber and reinforced concrete placed around the main piers. Again, it is intended to absorb the energy of any impact.

Fenders are not intended to absorb impacts from very large vessels. And so when the MV Dali, weighing more than 100,000 tonnes, made it past the protective dolphins, it was simply far too massive for the fender to withstand.

Video recordings show a cloud of dust appearing just before the bridge collapsed, which may well have been the fender disintegrating as it was crushed by the ship.

Once the massive ship had made it past both the dolphin and the fender, the pier – one of the bridge’s four main supports – was simply incapable of resisting the impact. Given the size of the vessel and its likely speed of around 8 knots (15 kilometres per hour), the impact force would have been around 20,000 tonnes.

Bridges are getting safer

This was not the first time a ship hit the Francis Scott Bridge. There was another collision in 1980, damaging a fender badly enough that it had to be replaced.

Around the world, 35 major bridge collapses resulting in fatalities were caused by collisions between 1960 and 2015, according to a 2018 report from the World Association for Waterborne Transport Infrastructure. Collisions between ships and bridges in the 1970s and early 1980s led to a significant improvement in the design rules for protecting bridges from impact.

Further impacts in the 1970s and early 1980s instigated significant improvements in the design rules for impact.

The International Association for Bridge and Structural Engineering’s Ship Collision with Bridges guide, published in 1993, and the American Association of State Highway and Transporation Officials’ Guide Specification and Commentary for Vessel Collision Design of Highway Bridges (1991) changed how bridges were designed.

In Australia, the Australian Standard for Bridge Design (published in 2017) requires designers to think about the biggest vessel likely to come along in the next 100 years, and what would happen if it were heading for any bridge pier at full speed. Designers need to consider the result of both head-on collisions and side-on, glancing blows. As a result, many newer bridges protect their piers with entire human-made islands.

Of course, these improvements came too late to influence the design of the Francis Scott Key Bridge itself.

Lessons from disaster

So what are the lessons apparent at this early stage?

First, it’s clear the protection measures in place for this bridge were not enough to handle this ship impact. Today’s cargo ships are much bigger than those of the 1970s, and it seems likely the Francis Scott Key Bridge was not designed with a collision like this in mind.

So one lesson is that we need to consider how the vessels near our bridges are changing. This means we cannot just accept the structure as it was built, but ensure the protection measures around our bridges are evolving alongside the ships around them.

Second, and more generally, we must remain vigilant in managing our bridges. I’ve written previously about the current level of safety of Australian bridges, but also about how we can do better.

This tragic event only emphasises the need to spend more on maintaining our ageing infrastructure. This is the only way to ensure it remains safe and functional for the demands we put on it today.

Colin Caprani, Associate Professor, Civil Engineering, Monash University

This article is republished from The Conversation under a Creative Commons license. Read the original article.

[Image: TODAY/YouTube]

Comments

John Romano 4 weeks ago

I’m an engineer from the old school. Drawing on velum and performing bridge waterway calcs on a Texas Instruments calculator. How dumb is it to think you can rebuild this structure. So I get that hazardous waste and petroleum products need to get moved, but common people….its time for a tunnel. Nice idea to try a really expensive design and hope another huge ship does not collide with it. Seriously just forget the bridge and build a tunnel no ship can ever impact. Nobody has common sense anymore.
1. Eugene Cook 3 weeks ago
  
  Is that we call a no brainer? Duh!
2. rytisg 4 weeks ago
  
  Uh, there already are two tunnels under the Baltimore harbor, the Fort McHenry tunnel with four tubes and 8 lanes, and the Harbor Tunnel with 2 tubes and 4 lanes. The Key bridge was built because hazardous materials are not allowed in tunnels. If a truck were to blow and breach the tunnel walls, it would be worse than what happened when the ship hit the Key bridge. Plus the tunnels were way more expensive to build than the bridge.
Nol Perreira 1 month ago

The problem is not that the bridge was designed for 20th century ships, but that the owners of the bridge and those responsible tof the bridge did not act proactively to protect the bridge. They had already been fore-warned by the previous incident that demolished a fender. A competent management would have reacted and improved the protection, if if were possible. As an appropriate action, the re-built bridge needs to have the protection upgraded so that the next incident will not destroy the replacement bridge.. Hopefully, the same bridge design can be re-instlled, but the fenders and protections improved.
Jaime Grant 1 month ago

I think we must also question the size of these ship loads. Existing bridges should be safeguarded against a disaster like this by restricting how much weight any single ship is carrying.
Nobilis Reed 1 month ago

I wonder if this bridge engineer has done any calculations to determine what protections would be sufficient to stop 200 million newton-seconds of momentum.