Among the biggest impending risks to society in the next decades are extreme weather occurrences. Those who have experienced a flood are well aware of the humbling effect of water. In addition to destroying homes and devasting wetlands and natural ecosystems, floods may wreak havoc on urban areas.
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But we are not powerless. In reaction to the threat posed by catastrophic flooding incidents, people have created a wide range of effective strategies to resist and manage water. We’re not talking about some magical ability to bend water, despite what the enthusiastic environmental engineer or civil engineer would say; rather, we’re talking about useful, scientific methods to control, anticipate, and stop severe floods. After defining these less-mystical-than-impressive methods, let’s look at how engineers and hydraulic modelers might contribute to averting catastrophic floods.
Planning and simulating floods
In the past, engineers would create massive levees, channels for rainwater to flow through, or, in more recent times, stormwater sewer networks to swiftly redirect water away from populous or environmentally significant regions in order to prevent or minimize floods. Even though many of these methods are still in use today, they are now supported by strong hydraulic modeling and simulation features that contemporary software offers. As will soon be clear, however, engineers’ capacity to avert floods is also being more influenced by the latest developments in artificial intelligence.
In order to prevent flooding, engineers must first have a thorough understanding of what a flood in a particular location may look like. In order to accomplish this, they must make use of strong hydraulic modeling tools that generate 2D models and perform calculations for overland flow, among many other characteristics, including the mapping of water courses and depths. We have developed and used Autodesk’s sophisticated flood and hydraulic modeling capabilities, so we know a thing or two about these technologies.
These kinds of powerful software programs may take in site and land data for a specific region, model different sized rainfall events, and then recreate the fundamental flow of water. As previously indicated, the capabilities of these technologies are even beginning to include artificial intelligence. With the use of an AI algorithm and the Machine Learning Deluge tool, modelers may simulate a flooding event and use the results to inform their decision-making on where to locate stormwater controls, such as ponds and pipelines.
Sustainably preventing flooding
Recall your most recent encounter with a storm pipe. Although it appeared obtrusive and industrial, it accomplished the task. Nonetheless, these inflexible, geometric constructions typically accomplish their goals by changing the course of natural movement and creating a visual contrast with their surroundings. In the industry, Sustainable Drainage Systems, also known as LiDs or Low Impact Developments (SuDS), are used to manage stormwater in a way that is beneficial to a particular ecosystem. This includes allowing for natural water infiltration and discharge, creating areas for wetlands habitats, and naturally replenishing groundwater sources.
SuDS encourage the prevention of catastrophic floods by drawing on lessons learned by nature over thousands of years, as opposed to only those learned by humans in the previous few decades. Indeed, I brought up the term “infiltration,” which has a lot to do with the idea of flooding. When we construct infrastructure, humans frequently choose impermeable surfaces. We use non-porous concrete to build highways and brick and stone structures, and we frequently do this in floodplains, which are normally nature’s natural buffer against flooding.
In the past, people have dealt with this by creating more impermeable drainage systems, such as sewage networks, pipelines, dams, and many other things. SuDS is a go back to the tried-and-true, and its use is growing. Autodesk is also well-versed in SuDS; in case you’re interested, we’ve even released a SuDS design handbook.
A scale-related issue
Flooding may be avoided in large part by using sustainable drainage design, hydraulic modeling, and proper engineering. An engineer may use It is a simulate a deluge, create a flood map, and make sure that storm drains and catchment basins are positioned correctly for a specific site, such as a housing development. They might even build such systems on the platform in tandem with their civil design tool. A general contractor or landowner may also utilize the tool to identify and successfully handle ponding or channeling concerns as the site is maintained and built.
A hydraulic modeler or city planner may use on a network or city size It is employed to calculate capital upgrades and create flood maps. The fact that governments frequently have to obtain and oversee project finance is one facet of flood management that we did not address in this piece. Engineers frequently use these potent techniques to solve this problem, which justifies capital expenditures and permits flood planning over a 50–100 year time horizon.
Ultimately, engineers use their own creativity and the strong hydraulic modeling tools at their disposal—with a little assistance from artificial intelligence these days—to help minimize floods. Although hydraulic modelers may not be considered water benders in the ethereal sense, they are the closest thing the earth has today, which is fortunate because flooding catastrophes would be far worse in the absence of their excellent work.