Arch Rubber Fender V Fender with High Energy Absorption Anti Impact Durability and Long Service Life
Arch Rubber Fender is a marine berthing protection system engineered for controlled impact energy absorption and structural load mitigation between vessel hulls and quay structures. The product is manufactured from marine grade elastomer compounds through controlled vulcanization molding processes, ensuring stable molecular structure, consistent mechanical properties, and long term resistance to compressive deformation under repeated operational cycles.
The structural configuration is based on an arch geometry designed to optimize force distribution during vessel contact. When subjected to berthing impact, the structure undergoes progressive elastic deformation, converting kinetic energy into controlled strain energy and reducing localized stress concentration on both marine vessels and port infrastructure.
The system is designed for marine engineering environments requiring stable docking performance, structural protection, and operational reliability under variable conditions including tidal fluctuation, wave motion, and continuous vessel traffic.
A container terminal rehabilitation project in Busan South Korea implemented Arch Rubber Fender systems to replace an aging berthing protection system that had exhibited uneven wear patterns and insufficient energy absorption performance under continuous container vessel operations. The terminal handles medium and large vessels with frequent berthing cycles which previously resulted in progressive damage to quay wall edges and increased maintenance requirements.
The engineering challenge involved reducing peak impact load transmission to concrete quay structures while maintaining stable vessel alignment during docking under tidal variation conditions. The existing system was unable to provide consistent load distribution leading to structural fatigue accumulation over time.
Arch Rubber Fender units were installed along the primary berthing zone with reinforced anchoring interfaces integrated into the existing quay structure. After implementation operational monitoring indicated improved load distribution characteristics and reduced localized stress concentration during vessel contact events. The system contributed to more stable docking behavior and reduced structural maintenance frequency under continuous operational conditions.


| Product Name | Arch Rubber Fender |
|---|---|
| Material | Natural Rubber, Silicone Rubber |
| Colour | Black, or Customized |
| Surface | Smooth |
| Size | Height: 200-1000mm Length: 1000-3500mm All Sizes Can Be Customized |
| Physical Properties | Polymer Content: 100% Virgin Working Temperature: -50℃~240℃ Tensile Strength: ≥16 Mpa Density: 90+/-5 Per 100mm in Hardness: 50-70 (shore A) Elongation: ≥400% |
| Features | 1. Through High Temperature Resistant 2. Excellent Tear Resistant, Oil Resistant, Aging Resistant 3. Resistant to Industrial Acid & Alkali and Good Elastic 4. Built as Per PIANC2002 |
| Application | Multi-Purpose-Terminals, RoRo Ramps, Passenger Vessel Terminals, Barge |
| Model | W [mm] | B [mm] | F [mm] | C [mm] | H [mm] |
|---|---|---|---|---|---|
| HM-ARF200H | 400 | 320 | 145 | 128 | 200 |
| HM-ARF250H | 500 | 410 | 175 | 160 | 250 |
| HM-ARF300H | 600 | 490 | 225 | 196 | 300 |
| HM-ARF400H | 800 | 670 | 300 | 260 | 400 |
| HM-ARF500H | 1000 | 840 | 375 | 325 | 500 |
| HM-ARF600H | 1200 | 1010 | 450 | 390 | 600 |
| HM-ARF800H | 1600 | 1340 | 600 | 520 | 800 |
| HM-ARF1000H | 2000 | 1680 | 750 | 650 | 1000 |
- Structural Load Distribution Engineering: The arch geometry is designed to convert concentrated impact forces into distributed compressive loading across the elastomer body. This structural mechanism reduces stress concentration and improves energy absorption efficiency during vessel berthing operations, supporting stable force transfer between vessel and quay structure.
- Marine Elastomer Material Technology: The system is manufactured using marine grade rubber compounds formulated for resistance to saltwater exposure ultraviolet radiation and ozone aging. The material maintains elasticity stability under long term cyclic compression and ensures consistent mechanical behavior in marine environments.
- Progressive Energy Absorption Mechanism: The fender operates through staged deformation behavior under external loading conditions. Initial impact energy is absorbed through elastic compression followed by controlled dissipation throughout the arch structure, enabling stable energy management during repeated docking cycles.
- Mounting Interface Structural Stability: The installation system is engineered for secure integration with concrete and steel quay structures. The mounting configuration ensures positional stability under multi directional load conditions and maintains alignment performance under long term operational use.
- Port and Terminal Infrastructure Systems: Applied in container terminals and bulk cargo ports where repeated vessel berthing requires stable impact absorption and structural protection of quay infrastructure under continuous operational cycles.
- Shipyard Docking and Maintenance Facilities: Used in vessel repair and maintenance environments where controlled docking conditions are required to reduce structural contact stress during positioning and servicing operations.
- Coastal and Offshore Engineering Structures: Installed in offshore platforms and coastal loading stations where vessel interaction occurs under wave influenced motion conditions requiring stable buffering performance and structural protection capability.
- Engineering Manufacturing Integration Capability: Hongruntong Marine operates as an integrated manufacturer combining design engineering material processing and production control systems to ensure consistent performance across marine fender product lines.
- Controlled Material Processing Technology: Advanced vulcanization and rubber compounding processes are applied to achieve stable mechanical properties including elasticity retention fatigue resistance and long term structural stability under cyclic loading conditions.
- Project Specific Engineering Customization: Technical design support is provided for different port structures vessel specifications and energy absorption requirements enabling tailored engineering solutions based on operational conditions.
- Global Project Experience and Quality Assurance System: The organization implements structured quality control procedures throughout production and delivery processes supporting consistent performance in international marine infrastructure applications.
Service life typically ranges from eight to fifteen years depending on operational frequency environmental exposure and maintenance practices under standard marine conditions.
The product is designed for installation on existing concrete and steel quay structures using standard anchoring systems without requiring major structural modification.
The system is suitable for marine environments including tidal variation saltwater exposure wave influence and repeated vessel impact within designed performance limits.
Customization is available for dimensional specifications hardness levels and mounting configurations based on vessel type and port infrastructure requirements.
Maintenance involves periodic inspection of structural condition mounting stability and surface wear to ensure long term operational reliability.


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