High Strength Plastic Geocell
Structural plastics such as polyethylene and polypropylene are often used in airfield geocell reinforcement. Their tensile strength can be varied by using different raw materials.
Once the sheets have been cut, they are then welded together to form the 3-dimensional cell structure. The finished product is then used in construction projects.
Light in Weight
Plastic geocells are 3-dimensional cellular structures that reinforce soil and stabilize roads. They are designed to distribute the weight of vehicles evenly across a road, which helps to minimize ground shifts over time. This also increases the lifespan of a road, reducing maintenance costs. These structures are made from polyethylene, which is a strong and durable material that can withstand many environmental elements.
They can be used for various construction applications, including road construction, slope erosion control, and landfills. They can help in stabilizing the base of asphalt and concrete roads, preventing rutting and deterioration. They are also ideal for terracing on sloping land. They can be perforated or non-perforated, depending on the project requirements. Perforated geocells are best for green infrastructure projects, as the holes allow water and air to pass through them. Non-perforated geocells have smooth walls that prevent the infiltration of water.
Singhal Industries Geocells provide a cost-effective, environmentally friendly tactic to soil strengthening. Using consistent cellular layouts, these structures reduce soil movement, decrease the width of shared coatings, and improve load-bearing capability. These features make them an excellent choice for roadways, railways, and landscaping. Moreover, they can be used to build greener and smarter infrastructure.
Good Lateral Restrict
A key feature of BaseLok Geocells is that they restrict soil movement laterally. This is important in preventing soil settlement and damage to footings, which can be expensive and time-consuming to repair. The lateral restriction of the geocells is determined by the type of infill material used, as well as the thickness and shape of the cells. Infill materials can also influence the shear strength of the geocells.
In previous studies, it was found that the shear strength of geocell-reinforced soil increases with increasing height of the geocells. However, this effect is limited by High Strength Plastic Geocell the shear resistance of the surrounding soil. In addition, the shear resistance of the geocell-reinforced soil varies according to the size and depth of the pocket openings, as well as the geometry of the pockets.
Moreover, the change of material properties due to low temperature is a serious issue in cold area engineering. Therefore, it is necessary to study the variation law of geocell strips at different temperatures. Using a uniaxial tensile test, this study compared the stress-strain curve characteristics, failure mode, and temperature sensitivity of geocell strips made of HDPE, PP, and PET at ambient temperatures of -5 degC, -20 degC, and -35 degC.
To install a Geocell, it is first necessary to prepare the site by removing any old material and placing a ground cover or sub-base layer as needed. Next, stake the Geocell’s with J-hook rebar anchor stakes or other suitable stakes. When the Geocells are in place, they can then be filled with aggregate and rake level.
High Tensile Strength
PRS Tough-Cells have the highest tensile strength of any geocell available. This helps to prevent creep and maintain confinement in the soil. In addition to preventing lateral movement, the high tensile strength also reduces erosion by weather and heavy or repetitive traffic.
The tensile test provides a quantitative measure of the stress required to induce plastic deformation. It is based on the Stepped geogrid manufacturers Isothermal Method (SIM) developed for aerospace, military and automotive applications. This SIM test uses a combination of load and temperature to simulate the effects of time. It can be used to estimate the time to failure of a geocell or a particular geotextile.
In this study, the tensile mechanical properties of three kinds of geocell strips commonly used in engineering, including HDPE, polypropylene and polyester (PET), were studied through uniaxial tensile testing at ambient temperatures of -5 degC, -20 degC, and -35 degC. The effects and differences of the different raw materials on the tensile mechanical behavior of geocell strips were also compared.
The results showed that the elongation of the HDPE geocell strip with a junction was higher than that of the PP and PET specimens. However, the elongation of the HDPE specimen was influenced by the ambient temperature, and it displayed an obvious necking phenomenon and a large lateral deformation when it reached the fracture point. Moreover, the tensile performance of the PP and PET specimens was less sensitive to the ambient temperature.
Environmentally Friendly
Plastic geocells are a great alternative to other construction materials for ground stabilization and erosion control. They help protect slopes from mass movements and can also be used to create a stable base for equipment storage and access roads on agricultural properties. These innovative devices allow for a significant reduction in the amount of material needed to construct a solid base, saving money and resources. This is especially useful for agricultural projects that rely on the use of machinery.
Airfield geocells are made from recycled plastic materials. They can be filled with vegetation, concrete, or soil. They are easily transportable and provide excellent stability and load-bearing capability. They can also be used to create a more aesthetically pleasing landscape. In addition, these devices are environmentally friendly and do not require the excavation of materials from the ground.
The tensile strength of plastic geocells is dependent on temperature, as well as the material from which they are made. This is particularly important in cold areas, where the elasticity of different materials can change with temperature. To study the effect of low temperature on the tensile strength of plastic geocells, they were analyzed using a tensile test machine. They were also soaked in consumables such as de-icing fluid and aviation fuel, and their resistance to these chemicals was examined.