Engineered solutions address the most challenging problems facing modern infrastructure. From slope stabilization and groundwater control to culvert rehabilitation and infiltration mitigation, each application is designed to restore performance, extend asset life, and minimize disruption. Explore the full range of problem-specific solutions available to keep critical systems operating at their best.
Targeted injection techniques are used to strengthen and stabilize soils placed behind retaining walls, abutments, and other structures. This process improves load transfer, reduces settlement, and enhances long-term stability.
Specialized grouting and waterproofing systems are applied to block water intrusion through basement walls and floors. This process protects interior spaces from flooding, prevents structural damage, and improves long-term durability.
Advanced sealing systems are installed to protect underground structures from groundwater intrusion. This process safeguards foundations, tunnels, and basements against deterioration while improving structural longevity.
Injection and sealing techniques are used to restore aging or deteriorated culverts without full replacement. This process stops infiltration, stabilizes surrounding soils, and extends service life while minimizing traffic disruption.
Low-permeability barriers are created through grout injection to block groundwater flow and control seepage. This method protects excavations, stabilizes embankments, and safeguards critical infrastructure from water-related damage.
Specialized grouting and reinforcement methods are used to strengthen and support existing foundations. This process increases load-bearing capacity, corrects settlement issues, and extends the service life of critical structures.
Rapid-response stabilization and sealing methods address soil failures, flooding, and structural instability during emergency conditions. These solutions restore safety, minimize downtime, and protect critical infrastructure from further damage.
Injection and reinforcement techniques are applied to stabilize weakened or failing embankments. This process improves slope integrity, prevents erosion, and restores long-term performance of transportation and utility corridors.
Specialized injection and containment methods are used to isolate or neutralize contaminants in soil and groundwater. This process supports regulatory compliance, protects surrounding ecosystems, and restores safe site conditions.
Grouting and reinforcement systems are installed to stabilize soils around excavations and open cuts. This process controls groundwater, prevents collapse, and creates safer working conditions for construction activities.
Engineered barriers are constructed within utility trenches to slow groundwater movement and prevent erosion. These breakers protect pipelines, reduce backfill loss, and improve long-term trench stability.
Targeted soil treatment techniques reduce swelling pressures caused by expansive clays. This process stabilizes foundations, minimizes seasonal movement, and improves long-term structural reliability.
Grouting and sealing systems are applied to manage groundwater movement around structures and excavations. This process prevents infiltration, reduces hydrostatic pressure, and protects infrastructure from water-related damage.
Sealing and grouting methods are used to eliminate infiltration and inflow in sanitary sewer systems. This process reduces treatment costs, prevents groundwater intrusion, and restores system efficiency.
Specialized grouting techniques are used to stabilize soils and fill voids commonly found in karst terrain. This process prevents sinkhole formation, restores ground stability, and protects overlying infrastructure.
Flexible sealing systems are applied to joints where service laterals connect to mainlines. This process prevents groundwater infiltration, stops soil migration, and extends the service life of underground pipelines.
Injection and reinforcement techniques are applied to stabilize mechanically stabilized earth (MSE) walls showing signs of movement or distress. This process restores structural integrity, improves load-bearing capacity, and extends wall service life.
Sealing and structural lining methods are used to repair aging or deteriorated manholes. This process stops infiltration, restores structural integrity, and extends service life without the need for full replacement.
Protective barriers are installed within soils or along structural surfaces to block moisture migration. This process prevents water damage, reduces deterioration, and safeguards below-grade infrastructure.
Flexible grouts and sealing systems are applied to restore watertight joints in pipelines. This process prevents infiltration, controls exfiltration, and extends the service life of underground utilities.
Specialized sealing systems are applied where pipes pass through walls, floors, or other structures. This process blocks water intrusion, prevents soil migration, and protects both the structure and the pipeline connection.
Grouting techniques are used to fill underground voids and stabilize soils in sinkhole-prone areas. This process restores ground integrity, prevents surface collapse, and protects overlying infrastructure.
Stabilization methods are applied to slopes affected by erosion, settlement, or instability. This process restores soil strength, prevents further movement, and protects transportation corridors and adjacent structures.
Engineered wall systems are constructed using grouting and reinforcement techniques to confine and stabilize soils. This process prevents migration, supports excavations, and provides long-term ground control for critical infrastructure.
Sealing and reinforcement methods are used to restore stormwater pipes, culverts, and structures affected by infiltration or deterioration. This process improves hydraulic performance, prevents failures, and extends system service life.
Injection techniques are used to densify weak soils and fill voids that contribute to ground subsidence. This process restores stability, prevents further settlement, and protects overlying infrastructure from damage.
Grouting systems are applied to seal joints and cracks in tunnel liners. This process blocks water infiltration, prevents soil migration, and extends the durability of underground transportation and utility structures.
Engineered barriers are installed within utility trenches to control groundwater flow and prevent erosion around buried pipelines. This process improves backfill stability, reduces maintenance needs, and extends pipeline service life.
Infrastructure challenges require more than temporary fixes—they demand engineered solutions built for durability and efficiency. Each method is designed to address specific problems such as settlement, infiltration, or erosion while minimizing disruption to surrounding operations. With advanced technologies and proven techniques, these solutions deliver lasting performance, reduced maintenance costs, and safer, more reliable infrastructure. Explore URETEK’s case studies to see how our proven solutions have solved these complex infrastructure challenges across the U.S.
Case StudiesHave a project in mind or need more details about our services? Connect with our team today to discuss your challenges and learn how URETEK solutions can deliver lasting results.