In modern civil engineering, seepage prevention and reinforcement are crucial to ensuring project safety and durability. Composite geomembrane, as an efficient ​​composite geosynthetic material​​, with its unique structure and excellent performance, has become an indispensable material in various fields such as water conservancy, environmental protection, and transportation. This article will take you deep into the world of composite geomembranes.What is a Composite Geomembrane?

A composite geomembrane is a geosynthetic material formed by laminating a ​​geotextile​​ to one or both sides of a ​​geomembrane​​ through specific processes. Its main purpose is to use the geotextile to protect the central impermeable geomembrane from damage while simultaneously performing multiple functions such as drainage and reinforcement.

Depending on the structure, composite geomembranes are mainly classified into ​​one cloth one membrane​​, ​​two cloths one membrane​​ (also called two fabrics one membrane), and even one cloth two membranes and multiple cloths multiple membranes. For example, "SN2/PE-16-400-0.5" indicates a composite of two layers of short-filament geotextile (SN2) and one layer of high-density polyethylene membrane (PE), with a tensile strength of 16KN, a total weight of the two geotextile layers of 400 grams, and a HDPE membrane thickness of 0.5 millimeters.

Outstanding Characteristics of Composite Geomembranes

Composite geomembranes combine the advantages of geotextiles and geomembranes. Their main performance characteristics include:

• ​​Excellent Impermeability:​​ The central plastic film (mainly HDPE, LDPE, PVC, or EVA) provides a ​​reliable impermeable barrier​​, effectively preventing the leakage of liquids and gases.
• ​​High Strength and Tear Resistance:​​ The composite structure gives it excellent physical and mechanical properties such as ​​tensile resistance, tear resistance, puncture resistance, and burst resistance​​, enabling it to withstand various stresses during construction and operation.
• ​​Chemical Corrosion Resistance and Aging Resistance:​​ Made from polymer materials with added anti-aging agents, it is ​​resistant to acids, alkalis, corrosion, and UV aging​​. It has a long service life and can adapt to unconventional temperature environments.
• ​​Drainage and Filtration Functions:​​ The geotextile layers on both sides not only protect the membrane material but also form ​​drainage channels​​, allowing water to drain along its interior while preventing soil particle loss, acting as a filter.
• ​​High Friction Coefficient:​​ Compared to a simple geomembrane, the non-woven fabric in the composite geomembrane provides a higher friction coefficient, ​​effectively preventing the covering layer from sliding​​ and increasing engineering stability.

Main Application Fields of Composite Geomembranes

Due to their comprehensive performance, composite geomembranes have a wide range of applications:

1. ​​Water Conservancy Projects:​​ They are the preferred material for anti-seepage treatment in ​​dams, reservoirs, channels​​, etc., preventing water loss and seepage damage to dam structures.
2. ​​Environmental Protection Projects:​​ Widely used for anti-seepage and anti-pollution treatment in ​​domestic waste landfills, industrial solid waste landfills, and sewage treatment plants​​, preventing harmful leachate from contaminating soil and groundwater.
3. ​​Transportation Engineering:​​ Used for ​​waterproofing and moisture prevention of road and railway subgrades​​, ​​tunnel lining drainage​​, and solving problems of soft foundation reinforcement and slope protection.
4. ​​Municipal, Industrial, and Agricultural Engineering:​​ Commonly used for anti-seepage in ​​artificial lakes, landscape water systems, storage ponds, aquaculture ponds​​, as well as ​​anti-seepage treatment for petroleum storage tank foundations, mining heap leach pads, and agricultural irrigation channels​​.
5. ​​Other Fields:​​ Can also be used in ​​salt field crystallization ponds, ash dams in the power industry, airport runway foundations​​, and other projects.

Key Construction Points and Precautions for Composite Geomembranes

Correct construction is crucial to ensuring the anti-seepage effect of composite geomembranes:

1. ​​Base Layer Treatment:​​ The laying surface should be flat and firm. Remove all sharp objects such as tree roots, turf, and sharp stones. Level with small-particle-sized sand or clay.
2. ​​Laying and Overlap:​​ During laying, it should not be stretched too tight. The parts buried in the soil at both ends should be corrugated to adapt to foundation deformation. The edges of adjacent materials require sufficient overlap width.
3. ​​Connection and Anchoring:​​ When connecting to surrounding structures (e.g., concrete), ​​expansion bolts and steel plate pressure strips​​ are often used for anchoring. Sealants like emulsified asphalt should be applied at the connection points to prevent leakage.
4. ​​Protective Layer Covering:​​ After laying, promptly cover with a ​​protective layer​​ (e.g., fine sand, clay, thickness not less than 30cm). Then, place block stones or concrete prefabricated blocks on top as an erosion protection layer. Avoid direct impact or heavy objects falling on the geomembrane during construction.
5. ​​Welding Technology:​​ For large-area laying requiring splicing, ​​thermal welding technology​​ is typically used for joining to ensure seam sealing.

How to Choose the Right Composite Geomembrane?

Selection requires comprehensive consideration of engineering requirements and product performance:

• ​​Define Engineering Needs:​​ Determine the required material's ​​mechanical indicators​​ (e.g., tensile strength, tear strength) and ​​physical indicators​​ (e.g., membrane thickness, geotextile area weight) based on the anti-seepage grade, withstandable water pressure, foundation conditions, and presence of chemical corrosion.
• ​​Refer to Design Standards:​​ Follow the requirements for material specifications, models, and execution standards in the engineering design drawings.
• ​​Common Specification Reference:​​
• ​​One cloth one membrane:​​ Base cloth approximately 200-1000g/㎡, membrane thickness 0.1-1.5mm.
• ​​Two cloths one membrane:​​ Base cloth approximately 80-600g/㎡, membrane thickness 0.2-1.5mm. A common example is 900g two cloths one membrane (where the total weight of the geotextile is 400g, and the HDPE membrane thickness is 0.5mm).
• ​​Emphasize Material Quality:​​ Choose reputable manufacturers and pay attention to the material's ​​durability, aging resistance, and uniformity​​.

Conclusion

Through clever material composition, composite geomembranes integrate multiple functions such as seepage prevention, drainage, reinforcement, and protection into one, providing an efficient and reliable solution for modern civil engineering. With the advancement of material technology and increasing engineering demands, the performance of composite geomembranes will continue to optimize, and their application fields will further expand, continuing to play an indispensable role in building safe, green, and sustainable infrastructure for humanity.