Engineering

Share this article:

Engineering

  • Join our comunity:

6 Rules for Rebuilding Infrastructure in an Era of ‘Unprecedented’ Weather Events

By: , Posted on: November 10, 2017

Flooding from Hurricane Harvey. Can the region rebuild infrastructure so that it can better withstand extreme weather events? AP Photo/David J. Phillip

Before Hurricane Harvey made landfall on Aug. 25, there was little doubt that its impact would be devastating and wide-ranging.

Unfortunately, Harvey delivered and then some with early estimates of the damage at over US$190 billion, which would make it the costliest storm in U.S. history. The rain dumped on the Houston area by Harvey has been called “unprecedented,” making engineering and floodplain design standards look outdated at best and irresponsible at worst.

But to dismiss this as a once-in-a-lifetime event would be a mistake. With more very powerful storms forming in the Atlantic this hurricane season, we should know better. We must listen to those telling a more complicated story, one that involves decades of land use planning and poor urban design that has generated impervious surfaces at a fantastic pace.

As the Houston region turns its attention to rebuilding and other cities consider ramping up efforts to make their infrastructure more resilient, it is this story that can provide valuable lessons for policymakers, planners, engineers, developers and the public. These lessons are all the more important against the backdrop of a Trump administration that has stripped requirements for infrastructure projects to consider climate impacts and may try to offer an infrastructure investment package.

We draw from our research as a social scientist and an engineer and from our experience helping to lead the Urban Resilience to Extreme Weather Events Sustainability Research Network (funded by the U.S. National Science Foundation). Here are six rules for investing in infrastructure for the 21st century that recognize the need to rethink how we design and operate our infrastructure.

If we design with the technologies, needs and climate conditions of the 20th century, we will no longer serve society and the hazards we will encounter now and in the future.

A strong foundation

Proactive maintenance first. In 2017, U.S. infrastructure was given a D+ by the American Society for Civil Engineering Infrastructure Report Card. The bill to repair all those deteriorating roads, bridges and dams would tally $210 billion by 2020, and $520 billion in 2040. For example, the US Army Corps of Engineers estimates there are 15,460 dams in the U.S. with “high” hazard ratings.

Yet, when our cities and states spend on infrastructure, it is too often on new infrastructure projects. And new infrastructure tend to emulate the models, designs and standards that we’ve used for decades – for instance, more highway capacity or new pipelines.

Meanwhile, resources for long-term maintenance are often lacking, resulting in a race to scrape together funding to keep systems running. If we want to get serious about avoiding disasters in a rapidly changing world, we must get serious about the maintenance of existing infrastructure.

Invest in and redesign institutions, not just infrastructure. When analyzing breakdowns in infrastructure, it is tempting to blame the technical design. Yet design parameters are set by institutions and shaped by politics, financing and policy goals.

So failures in infrastructure are not just technical failures; they are institutional ones as well. They are failures in “knowledge systems,” or the ability to generate, communicate and utilize knowledge within and across institutions.

A temporary levee built after Hurricane Katrina. A number of people knew the vulnerability of the levee system before Katrina but the institutions responsible did not adequately respond. FEMA/Andrea BooherCC BY

For example, the levee failures during Hurricane Katrina are often interpreted as technical failures. They were, but we also knew the levees would fail in a storm as powerful as Katrina. And so the levee failures were also failures in institutional design – the information about the weakness of the levees was not utilized in part because the Hurricane Protection Systemwas poorly funded and lacked the necessary institutional and political power to force action.

In the wake of Harvey, basic design and floodplain development parameters, like the 100-year flood, are being acknowledged as fundamentally flawed. Our ability to design more resilient infrastructure will depend on our ability to design more effective institutions to manage these complex problems, learn from failures and adapt.

Resilience and uncertainty

Design for climate change. When it comes to infrastructure’s ability to handle more extreme events that are predicted to come with climate change, the primary problem is not bad engineering or faulty technical designs. Instead, it’s that infrastructure are typically sized based on the intensity and frequency of historical events. Yet these historical conditions are now routinely exceeded: since 1979, Houston alone has experienced three 500-year storms.

Climate change will make preparing for future storms much harder. These events are not just associated with precipitation and inland flooding but include more extreme heat, cold, drought, wildfires, coastal flooding and wind. Buildings, roads, water networks and other infrastructure last decades and designing for historical events may result in more frequent failure as events become more frequent or intense with climate change. Infrastructure designers and managers must shift from risk-based to resilience-based thinking, so that our systems can better withstand and bounce back from these extreme events.

Individual decisions on flood drainage for specific locations in heavily paved Houston may have been considered sufficient but planners need to consider how the entire region can handle flooding and other extreme weather events. OmCC BY-NC-ND

Manage infrastructure as interconnected and interdependent. In his 1987 essay, “Atchafalaya,” writer John McPhee explores efforts by the U.S. Army Corps of Engineers to control the Atchafalaya and Mississippi River systems. He brilliantly showed that rather than bringing predictability to a complex and meandering riverine system, the Old River Control system created unpredictability. “It’s a mixture of hydrologic events and human events… This is planned chaos… Nobody knows where it’s going to end.”

While floodplain management has made advances since then, the impact of development and infrastructure design is still often considered on a piecemeal basis. As Montgomery County engineer Mark Mooney noted in a recent Houston Chronicle article, “I can show you on any individual project how runoff has been properly mitigated. Having said that, when you see the increase in impervious surfaces that we have, it’s clear the way water moves through our county has changed. It’s all part of a massive puzzle everyone is trying to sort out.”

Infrastructure planning and design must consider the legacy of past decisions and how risks build up over time as ecological, technological and human systems interact in increasingly uncertain and complex ways.

Infrastructure and equity

Create flexible infrastructure. Given that our infrastructures are centralized and satisfy demands that don’t change rapidly (we use water and electricity much in the way we did over the past century), they tend to be inflexible. Yet we need our urban systems and the infrastructure that support them to be resilient. And flexibility is a necessary precondition for resilience.

Current designs favor robustness and redundancy. These infrastructure tend to be difficult to change and the managing institutions are often structured and constrained in ways that create barriers to flexibility. Consider the difference in flexibility of landline versus mobile phones, in terms of both use and changing the hardware. Similarly, new strategies are needed to incorporate flexibility into our infrastructure. In the case of hurricanes, roadways with smart signaling and controls that dynamically adjust stoplights and reverse lanes to allow vehicles to evacuate quickly would be of significant value.

Design infrastructure for everyone. Large disasters almost always highlight systemic social inequalities in our communities, as we saw in the 1995 Chicago heat waveHurricane Katrina and now Hurricane Harvey.

Yet as cities rebuild and other cities watch to glean lessons, we consistently sidestep the historical legacies, public policies and political-economic structures that continue to make low-income and minority populations, such as homeless people, more vulnerable to extreme weather events. For this to change, infrastructure must be designed with the most vulnerable in mind first.

Too often the services delivered by climate-resilient infrastructure are first built for the communities that have the economic and political power to demand them, resulting in what some have called ecological gentrification. Policymakers and planners must engage diverse communities and ensure that infrastructure services are designed for everyone – and communities need to demand it.

By Thaddeus R. Miller, Assistant Professor, School for the Future of Innovation in Society and The Polytechnic School, Arizona State University and  Mikhail Chester, Senior Sustainability Scientist, Julie Ann Wrigley Global Institute of Sustainability, Arizona State University. This article was originally published in The Conversation under a Creative Commons Attribution No Derivatives license. Read the original here.


Want to read more?

risk modeling for hazards and disasters

Risk Modeling for Hazards and Disasters

  • Includes high profile case studies such as the Newcastle earthquake, Hurricane Andrew and Hurricane Katrina
  • Provides crucial information on new ideas and platforms that will help address the new demands for risk management and catastrophe risk reporting
  • Presents the theory and practice needed to know how models are created and what is and what is not important in the modeling process
  • Covers relevant new science in risk modeling, indirect losses, assessment of impact and consequences to insurance losses, and current changes in risk modeling practice, along with case studies

The book is available now on ScienceDirect.  Want your own copy? Enter STC317 at the checkout when you order on Elsevier.com to save up to 30%

Connect with us on social media and stay up to date on new articles

Engineering

Engineering brings science and technology out of the lab and into the real world. Often without thinking about it, we engage every day with technology that is the product of careful, precise design and execution by engineers in electronics, optics, and communications; embedded systems; automotive, aerospace, and marine; mechanical; and many other disciplines. For decades, Elsevier has maintained and grown extensive collections in these and other cutting-edge areas, like biomechanics and nanotechnology, through our trusted imprints: Newnes, Academic Press, and Woodhead Publishing. In addition, our powerful online platforms like Knovel and Engineering Village help streamline research and development processes for users around the world.

Social Media Auto Publish Powered By : XYZScripts.com