High-elasticity impact- and abrasion-resistant polymer mortar has become a core material in the protection of hydraulic structures against impact and abrasion, owing to its excellent mechanical properties and durability. It demonstrates outstanding protective effects, particularly in critical areas such as hydraulic wave-splash zones and hydropower station gate piers.

I. Material Characteristics and Protective Mechanism

This material is based on polymer-modified cementitious substrates, and its protective capability stems from three key characteristics:

1. High Elasticity and Toughness: The introduced polymer molecular chains effectively absorb and dissipate impact energy. When subjected to high-velocity water flow, sediment, or floating ice impact, the material does not undergo brittle spalling like ordinary concrete. Instead, it buffers stress through micro-deformation, significantly reducing material loss.

2. Exceptional Impact and Abrasion Resistance: The formed dense microstructure and high-strength cementitious matrix effectively resist the abrasion and cutting actions of suspended and bed loads (such as sediment and pebbles) in water flow. Its wear resistance is several times higher than that of ordinary concrete.

3. Strong Bonding and Impermeability: It exhibits high bonding strength with old concrete substrates, enabling integrated stress distribution. Simultaneously, its extremely low permeability effectively prevents the intrusion of water and harmful ions, avoiding internal damage caused by freeze-thaw cycles and chemical erosion, thereby enhancing durability.

II. Application in Hydraulic Wave-Splash Zones

Wave-splash zones of hydraulic dams, such as upstream slopes, stilling basins, and spillways, endure long-term severe wave沖刷, wet-dry cycles in fluctuating water level areas, and potential ice impact.

• Application Areas: Primarily used for surface protection in flow-passing areas of the aforementioned regions, often applied as a 20-50mm thick impact- and abrasion-resistant overlay.

• Solution: In such areas, its high elasticity converts the substantial kinetic energy of waves into deformation energy within the material itself, dissipating it and reducing direct impact damage. Its excellent abrasion resistance withstands continuous wear from sediment-laden waves on slopes. During construction, it is typically applied by spraying or manual troweling onto prepared (roughened, cleaned, moistened) concrete substrates to form a tough, intact protective layer, effectively extending the service life of structures in wave-splash zones and reducing economic losses and operational risks from frequent repairs.

III. Application in Hydropower Station Gate Piers

Gate piers in hydropower stations, especially the concrete in the hinge areas of radial gate arms, operate in extremely harsh conditions. They endure not only the complex effects of high-velocity (up to 30-40m/s) discharge flow but also direct impact from water jets behind the gate, vibration, and cavitation erosion.

• Application Areas: Mainly applied to upstream faces, side surfaces, and areas around gate slots that are prone to high-velocity flow impact and cavitation damage.

• Solution: Here, the material's core role is to resist impact vibration and cavitation. Its toughness buffers impacts and vibrations from gate operation and flow pulsations, preventing fatigue cracking in concrete. The dense structure and high strength effectively resist沖磨from high-velocity sediment-laden flow and significantly increase the material's critical cavitation strength, making it more resistant to damage from shock waves generated by collapsing cavitation bubbles. Construction typically involves vertical formwork pouring or high-pressure jetting to form a reinforcement layer tightly integrated with the base concrete, greatly enhancing the gate piers' disaster resistance and operational safety.

IV. Key Points of Construction Techniques