What is a levee? Types, advantages and building steps

Levees act as protective barriers, helping to prevent or minimize flooding by confining water within designated channels or floodplains. They play a crucial role in safeguarding communities, infrastructure, and agricultural lands from the destructive impacts of flooding.

Different types of levees

Levees are structures built along rivers, coastlines, or other bodies of water to provide protection against flooding. There are several different types of levees, each designed for specific conditions and purposes. Here are some common types of levees:

1. Embankment Levees: Embankment levees are the most common type of levee and consist of compacted soil or fill material. They are typically constructed in a trapezoidal shape with a wide base and sloping sides.
2. Sheet Pile Levees: Sheet pile levees are constructed using interlocking steel or concrete sheet piles driven into the ground. These piles create a barrier against water intrusion.
3. Floodwall Levees: Floodwall levees are vertical walls made of concrete, steel, or other materials. They are typically built in urban areas or where space is limited.
4. Ring Levees: Ring levees are circular or semicircular levees built around low-lying areas or communities. They enclose the area, providing flood protection from surrounding water bodies.
5. Backwater Levees: Backwater levees are constructed to protect against flooding caused by water backing up from downstream or tidal surge.
6. Overbank Levees: Overbank levees are built farther away from the river channel to accommodate floodwaters during periods of high water levels.
7. Breakaway Levees: Breakaway levees, also known as fuse plug levees, are designed to intentionally breach in areas of extreme flooding.
8. Tidal Levees: Tidal levees are constructed along coastlines or estuaries to protect low-lying areas from tidal surges. They are designed to withstand the forces of wave action and high tides.

What is the difference between a dam and a levee?

A dam and a levee are both flood control structures, but they have distinct differences in their design, purpose, and function. Here are the key differences between a dam and a levee:

1. Purpose: Dams are primarily built to store water, control its release, and generate hydroelectric power. They are constructed across rivers or streams to impound water, creating reservoirs for various purposes like irrigation, drinking water supply, and flood control. Levees, on the other hand, are constructed to provide protection against flooding. They act as barriers along rivers, coastlines, or other bodies of water to prevent floodwaters from inundating adjacent areas.
2. Design and Construction: Dams are typically large and engineered structures made of compacted earth, rock-fill, concrete, or a combination of these materials. They are designed to withstand the forces of water pressure and have spillways or gates to control water release. Dams often require extensive planning, engineering, and construction processes. Levees, in contrast, are generally earthen structures built using compacted soil or fill material. They are constructed parallel to the water body and are designed to contain and redirect floodwaters.
3. Water Storage vs. Water Diversion: Dams are primarily built to impound water, creating reservoirs that store large quantities of water for various purposes. They regulate the flow of water downstream and release it in a controlled manner. Levees, however, do not store water but are intended to redirect floodwaters away from protected areas. They act as barriers, guiding water to flow around the protected region.
4. Control of Water Flow: Dams have mechanisms such as spillways, gates, and turbines to control the flow of water, enabling regulation of water levels and release during different conditions. Levees, on the other hand, do not have such control mechanisms. They rely on their structural integrity and elevation to prevent floodwaters from overtopping and reaching protected areas.
5. Location and Scale: Dams are typically constructed on rivers or streams and can be massive structures, spanning across the water body. They often involve the creation of reservoirs covering large areas. Levees, on the other hand, are built along rivers, coastlines, or other water bodies. They can vary in scale, ranging from small local levees protecting specific areas to extensive systems protecting entire regions.

Levee construction: Steps to building a levee

Here are the general steps involved in building a levee:

1. Feasibility and Design: The first step is to conduct a feasibility study and design the levee. This involves assessing the flood risks, studying the topography and hydrology of the area, and determining the required height, alignment, and dimensions of the levee.
2. Site Preparation: The construction site needs to be prepared before the actual levee construction begins. This includes clearing vegetation, removing any obstructions or debris, and conducting necessary grading and leveling of the land.
3. Excavation and Foundation: The next step is to excavate the foundation of the levee. The foundation is typically dug to a specified depth, removing unsuitable soil and creating a stable base for the levee.
4. Levee Construction: The construction of the levee itself follows several phases:

1. Placement of Fill Material: Suitable fill material, such as compacted clay, sand, or engineered materials, is placed in layers and compacted to achieve the desired density and stability. The fill material is usually placed in lifts, and each layer is compacted using heavy equipment to ensure proper compaction.
2. Shaping and Sloping: As the fill material is placed, the levee is shaped to the required cross-section, which is often trapezoidal. The sides of the levee are sloped to provide stability and prevent erosion.
3. Reinforcement: Depending on the design and engineering requirements, the levee may incorporate reinforcement elements. These can include geotextiles, geosynthetic products, or concrete revetments to enhance stability and erosion resistance.
4. Drainage Systems: Adequate drainage systems, such as toe drains, seepage berms, and relief wells, are installed within the levee to manage water seepage and control pore pressure. These drainage systems help maintain the stability of the levee.
5. Access and Maintenance Structures: Access ramps, floodgates, and other structures necessary for maintenance and monitoring of the levee are built as part of the construction process.

1. Compaction and Testing: Throughout the construction process, the compacted fill material is regularly tested to ensure proper compaction and density. Various testing methods, such as nuclear density testing or cone penetration testing, may be used to verify the quality of the fill material.
2. Vegetation and Erosion Control: Once the main levee construction is completed, vegetation may be planted on the slopes and crest of the levee to enhance stability and provide erosion control.
3. Ongoing Maintenance: After construction, ongoing maintenance is essential to ensure the levee’s long-term effectiveness. Regular inspections, erosion repairs, vegetation management, and monitoring of drainage systems are necessary to keep the levee in good condition.

---

Read more: What is a geosynthetic?

---

Construction of levees using geomembranes

Here are the steps involved in constructing levees using geomembranes:

1. Feasibility Study and Design: Conduct a feasibility study to assess the suitability of using geomembranes for levee construction in the specific site conditions. Evaluate the soil properties, hydrological factors, and potential seepage issues.
2. Excavation and Foundation Preparation: Excavate the foundation area of the levee to the required depth, ensuring a stable base for the geomembrane liner. Remove any unsuitable soil or debris and level the surface.
3. Geomembrane Installation: Roll out the geomembrane liner along the foundation area of the levee. Carefully position and align the liner to cover the intended area, allowing for overlaps at joints and connections.
4. Seaming and Joining: Seam or join the geomembrane panels together using appropriate techniques, such as heat fusion, chemical bonding, or mechanical fastening.
5. Anchor Trenches and Ballasting: Excavate anchor trenches along the edges of the geomembrane liner. Place anchor or ballast materials, such as soil, concrete, or sandbags, in the trenches to secure and hold down the geomembrane in place.
6. Overlapping and Termination: Where necessary, create overlaps and terminations of the geomembrane liner to ensure continuous coverage and prevent seepage.
7. Protection and Cover: Provide protection for the geomembrane liner by placing suitable materials, such as geotextiles or geogrids, over it.
8. Fill Placement and Compaction: Backfill the levee with suitable fill material, compacting it in layers to achieve the required density and stability.
9. Drainage and Erosion Control: Incorporate drainage systems, such as toe drains or relief wells, within the levee to control seepage and manage water pressure.
10. Ongoing Inspection and Maintenance: Regularly inspect the geomembrane liner and levee for any signs of damage, degradation, or seepage.

---

Read more: What is a geogrid?

---

Advantages of levees

Here are some key advantages of levees:

1. Flood Protection
2. Risk Reduction
3. Infrastructure Protection
4. Agricultural Benefits
5. Land Use and Development
6. Water Management
7. Enhanced Resilience

Disadvantages of levees

Here are some common disadvantages associated with levees:

1. Limited Effectiveness
2. False Sense of Security
3. Increased Risk of Failure
4. Altered Hydrological Patterns
5. Cost and Maintenance
6. Environmental Impact
7. Encouragement of Development in Floodplains

Conclusion

In conclusion, levees are man-made structures designed to provide flood protection by confining and controlling the flow of water. They play a critical role in safeguarding communities, infrastructure, and agricultural lands from the destructive impacts of flooding. However, proper design, construction, and ongoing maintenance are essential to ensure their effectiveness and mitigate potential risks.