Material Purity: The copper used has a purity of ≥99.95%, ensuring minimal electrical resistance. Impurities (such as iron or oxygen) are strictly controlled (≤0.05%) to avoid reducing conductivity or causing corrosion in saltwater.

Cross-Sectional Area: The 50mm² area is standardized to balance current capacity and installation Flexibility. For reference, a 50mm² copper conductor has a nominal diameter of approximately 7.98mm (for a solid conductor) or a stranded structure with 19 strands of 2.05mm diameter each.

Current-Carrying Capacity: The continuous current rating varies based on environmental conditions:

Stranding Structure: The conductor uses a class 5 stranded design (per IEC 60228), meaning it is composed of multiple thin Copper Strands twisted together. This structure enhances flexibility (minimum bending radius: 12× cable outer diameter) and resistance to fatigue from underwater currents or installation stress. For example, a 50mm² conductor typically consists of 19 strands (diameter 2.05mm) or 37 strands (diameter 1.38mm), depending on the required flexibility for specific projects.

XLPE Insulation:

Metallic Water Barrier:

Outer Sheath:

Hydrostatic Pressure Resistance:

Temperature Cycling Resistance: Survives 50 cycles of -40°C (4 hours) to 90°C (4 hours) with no cracking or loss of insulation performance.

UV Resistance: For shallow-water applications (exposed to sunlight), the outer sheath includes UV stabilizers (e.g., benzophenones) to resist degradation. After 1000 hours of UV exposure (per ISO 4892-3), the sheath retains ≥80% of its original tensile strength.

Impact Resistance: Can withstand a 1kg weight dropped from 1m (per IEC 60811-504) with no damage to the insulation or conductor.

Water Depth Rating: As noted earlier, sheath thickness and barrier reinforcement are adjusted for different depths. For example, deep-sea cables may include an additional layer of aramid fiber (e.g., Kevlar) between the water barrier and sheath to enhance tensile strength (up to 50kN).

Armour Layer: Galvanized steel wire armour (GSWA) is available as an optional add-on. The armour uses steel wires with a diameter of 1.2mm–2.0mm, twisted around the cable in a 1+6 or 1+6+12 configuration. It provides impact resistance (withstands 5kN impact force) and rodent protection (critical for coastal areas with burrowing animals).

Color Coding: The outer sheath can be customized to specific colors (e.g., red for Power Cables, blue for Control cables) to facilitate identification during installation and maintenance.

Termination: Pre-terminated cables use underwater-rated connectors (IP68/IP69K) with materials such as brass (plated with nickel) or 316 stainless steel. The connectors are sealed with O-rings made of nitrile rubber (NBR) or fluorocarbon rubber (FKM) for water tightness.

High Conductivity: With a conductivity of 100% IACS (International Annealed Copper Standard) at 20°C, it minimizes power loss during transmission. For example, a 1000m length of 50mm² copper conductor has a resistance of only 0.0358Ω at 20°C, compared to 0.094Ω for an Aluminum Conductor of the same size.

Corrosion Resistance: ETP copper forms a thin, stable oxide layer (CuO/Cu₂O) when exposed to air or water, preventing further corrosion. In saltwater, this layer is reinforced by the cable’s protective sheaths, ensuring long-term conductor integrity.

Workability: ETP copper is easily drawn into thin strands and twisted, enabling the flexible stranded structure required for underwater installation.

Cross-Linking Process: The XLPE is produced using a peroxide cross-linking method (per IEC 60811-301), which creates strong chemical bonds between polyethylene molecules. This process eliminates the “cold flow” (creep) that plagues standard polyethylene, ensuring the insulation retains its shape and electrical properties under pressure.

Water Resistance: XLPE has a low water absorption rate because cross-linking reduces the number of free molecules that can absorb moisture. This prevents “water treeing”—a common issue in underwater cables where moisture forms conductive paths in the insulation, leading to breakdown.

Thermal Stability: The cross-linked structure allows XLPE to withstand higher temperatures than standard polyethylene, making it suitable for cables that generate heat during high-current operation (e.g., powering offshore wind turbines).

Aluminum-Polyethylene Laminate (ALP): This barrier consists of a thin aluminum foil bonded to a polyethylene layer. The aluminum provides an impermeable barrier to water, while the polyethylene layer adheres to the XLPE insulation, ensuring a tight seal. ALP is lightweight (density ~2.7g/cm³) and cost-effective, making it ideal for shallow and medium-depth cables.

Copper Tape: Copper tape offers superior corrosion resistance compared to aluminum, making it suitable for deep-sea or polluted water environments. It also provides electromagnetic shielding, which is beneficial for cables used in conjunction with sensitive communication equipment (e.g., subsea sensors).

Thermoplastic Polyurethane (TPU): TPU is a elastomeric material known for its exceptional flexibility, abrasion resistance, and oil resistance. It is ideal for cables installed in areas with high mechanical stress (e.g., seabeds with rocks or ship traffic) because it can stretch and recover without cracking. TPU also has good low-temperature flexibility, remaining pliable at -40°C—critical for polar or deep-sea applications.

Chlorosulfonated Polyethylene (CSP): CSP is a chemically modified polyethylene with chlorine and sulfonyl chloride groups. It offers excellent resistance to ozone, UV radiation, and harsh chemicals (e.g., oil, grease, and industrial pollutants). CSP is often used in coastal industrial areas or near oil rigs, where the cable may be exposed to chemical contaminants.

Galvanized Steel Wires: The wires are made from low-carbon steel (S235JR) with a hot-dip galvanized coating (zinc thickness ≥85μm). The zinc coating provides corrosion resistance, while the low-carbon steel offers high tensile strength (≥500MPa).

Aramid Fiber Reinforcement: In deep-sea cables, aramid fiber (e.g., Kevlar) is added to the armour layer. Aramid has a tensile strength five times that of steel (per unit weight) and is resistant to corrosion and high temperatures. It helps the cable withstand the extreme hydrostatic pressure of deep waters and reduces the overall weight of the cable.

Copper Wire Rods: Inspected for purity (via atomic absorption spectroscopy), tensile strength (≥300MPa), and diameter tolerance (±0.02mm). Samples are also tested for conductivity to ensure they meet 100% IACS standards.

XLPE Compound: Tested for melt flow rate (MFR: 0.5g/10min–1.5g/10min at 190°C/2.16kg), density, and electrical insulation properties. A small batch of XLPE is extruded into test samples and subjected to water absorption and dielectric strength tests.

Metallic Barriers: ALP is checked for aluminum foil thickness and adhesion strength; copper tape is tested for thickness, tensile strength, and corrosion resistance (via salt spray testing).

Sheath Materials: TPU and CSP are tested for Shore hardness, tensile strength, elongation at break, and chemical resistance. Samples are immersed in saltwater for 1000 hours to verify no degradation.

Tape Preparation: The ALP or copper tape is unwound from a reel and pre-heated to 60°C–80°C to activate the adhesive (for ALP) or soften the tape (for copper tape), improving adhesion to the XLPE insulation.

Wrapping: The machine wraps the tape around the insulated conductor with 100% overlap (no gaps) and a tension of 50N–80N (adjusted based on tape thickness). For copper tape, an additional conductive adhesive is applied to ensure electrical continuity.

Quality Check: After wrapping, the barrier’s adhesion strength is tested using a peel test (≥5N/cm for ALP, ≥8N/cm for copper tape), and a visual inspection checks for creases or gaps (which could allow water ingress). Defective sections are re-wrapped.

Pre-Heating: The barrier-wrapped conductor is pre-heated to 70°C–90°C to improve adhesion between the barrier and sheath.

Extrusion: The TPU or CSP compound is fed into an extruder with a screw diameter of 90mm–120mm. The extruder temperature is controlled (180°C–200°C for TPU, 160°C–180°C for CSP) to ensure smooth melting. The molten sheath material is forced through a cross-head die to form a uniform layer (thickness: 2.5mm–4.0mm, depending on water depth rating).

Cooling and Sizing: The Sheathed Cable is cooled in a two-stage water bath (first stage: 60°C–70°C, second stage: 20°C–30°C) to prevent shrinkage. A vacuum sizing tank ensures the sheath’s outer diameter is uniform (tolerance: ±0.2mm).

Final Inspection: The cable undergoes a series of tests, including:

Armour Application: For cables with galvanized steel wire armour (GSWA), a wire stranding machine twists steel wires (diameter: 1.2mm–2.0mm) around the sheathed cable in a 1+6 or 1+6+12 configuration. The armour is tested for tensile strength (≥50kN) and adhesion (no wire loosening allowed).

Termination Installation: Pre-terminated cables are fitted with underwater-rated connectors (IP68/IP69K) using a crimping machine (crimp force: 50kN–100kN) to ensure a secure connection. The terminated end is submerged in 3.5% NaCl solution for 48 hours, with no current leakage (tested using a megohmmeter).

Color Coding: The outer sheath is colored using masterbatch additives during extrusion. A spectrophotometer verifies the color matches the customer’s specifications (ΔE ≤1.0, per CIELAB color space).

Application in Offshore Wind Farms:

Cable Configuration: For array cables (connecting turbines), the 50mm² cable is configured with a TPU outer sheath (2.5mm thickness) for flexibility and abrasion resistance, plus a metallic water barrier (ALP) to prevent saltwater ingress. For export cables (longer distances, up to 100km), the cable includes an additional galvanized steel wire armour (GSWA) layer to withstand mechanical stress during installation (e.g., pulling from a lay vessel to the seabed) and protect against anchor damage from passing ships.

Performance Benefits: The high-purity copper conductor minimizes power loss (≤3% per 10km), ensuring efficient transmission of electricity generated by wind turbines (typically 2MW–5MW per turbine). The TPU sheath’s resistance to UV radiation and saltwater corrosion extends the cable’s service life to 20–25 years, aligning with the 25-year operational lifespan of most offshore wind farms.

Application in Tidal Turbines:

Application in Subsea Wellheads:

Application in ROVs:

Application in Submersible Pumps:

Application in Underwater Lighting:

Application in Underwater Aerators:

Application in Water Temperature Sensors:

Drum Material:

Cable Protection on Drums:

Drum Labeling and Documentation:

Box Material: Double-walled corrugated cardboard (thickness 8mm) with a bursting strength of ≥2000kPa—sufficient to withstand stacking and minor impacts during shipping.

Interior Protection: The cable is coiled into a compact circle (diameter 300mm–500mm) and wrapped in bubble wrap (thickness 5mm) to prevent kinking and abrasion. A silica gel packet (10g) is added to the box to absorb residual moisture, ensuring the cable remains dry.

Labeling: The box is labeled with the same product information as bulk drums, plus a “Fragile” sticker to alert logistics providers to handle the package with care. Sample boxes also include a brief product brochure highlighting the cable’s key features and applications.

Indoor Storage: Cables should be stored in a dry, well-ventilated warehouse with a temperature range of -5°C to 40°C and relative humidity ≤70%. Avoid storing near heat sources (e.g., heaters, boilers) or chemicals (e.g., oil, solvents) that could damage the outer sheath.

Drum Storage: Wooden drums should be placed on level ground, with wooden blocks (height 100mm) under the drum ends to prevent rolling. Do not stack wooden drums higher than 2 layers; steel drums can be stacked up to 3 layers (with a weight limit of 1000kg per layer).

Unused Cable: If a drum is partially used, the remaining cable should be rewound tightly onto the drum and covered with the original PE film and kraft paper. The drum should be sealed with tape to prevent moisture and dust ingress. Unused cables should be inspected for sheath damage (e.g., cracks, scratches) before installation.

Shelf Life: When stored correctly, the cable has a shelf life of 3 years from the production date. After 3 years, the cable should undergo electrical testing (insulation resistance, withstand voltage) before use to ensure performance.

Container Shipping: Cables are shipped in 20ft or 40ft standard shipping containers (ISO 6346). Wooden drums are secured to the container floor using steel bolts (M16) and wooden wedges to prevent rolling during rough seas. Steel drums are stacked (up to 3 layers) and secured with steel straps (width 50mm) to the container’s load-bearing points.

Moisture Protection: The container is lined with a moisture-absorbing blanket (100g/m²) to reduce condensation during transit (a common issue in sea shipping). A humidity sensor is placed inside the container to monitor moisture levels, with data accessible to the customer via a mobile app.

Transit Time and Tracking: Sea transportation typically takes 15–45 days, depending on the route (e.g., China to Europe: 25–35 days; China to North America: 15–25 days). The customer receives a container tracking number (from the shipping line) to monitor the shipment’s progress in real time via the shipping line’s website or mobile app. The manufacturer’s logistics team also provides weekly updates, including port arrival/departure times and any potential delays (e.g., port congestion).

Truck Transportation: Heavy-duty trucks with flatbed or enclosed trailers are used. Enclosed trailers are recommended for long-distance transport (≥500km) to protect the cable from weather (rain, snow) and road debris. Flatbed trailers are suitable for short distances (≤300km) or for oversized steel drums that cannot fit in enclosed trailers. The drums are secured to the trailer using steel straps (tension ≥5kN) and wooden blocks to prevent shifting during transit.

Railway Transportation: For large bulk orders (≥50 drums), railway transportation is more cost-effective than trucks. The cables are shipped in railway containers (ISO 6346) with the same moisture protection measures as sea containers (moisture-absorbing blankets, humidity sensors). Railway transit time is typically 2–7 days for domestic orders and 5–14 days for cross-border orders (e.g., Germany to Poland).

Last-Mile Delivery: For delivery to construction sites or remote coastal areas, the manufacturer coordinates with local logistics providers to ensure the cable reaches the final destination. This may involve using smaller trucks with off-road capabilities or partnering with port authorities to arrange barge transportation for island destinations.

Cargo Planes: Cables are shipped in air cargo containers (ULD containers) with weight limits of 100kg–1000kg. Small-length cables (10m–50m) are packaged in cardboard boxes, while longer lengths (100m–500m) are wound onto lightweight aluminum drums (to reduce shipping weight).

Speed and Cost: Air transportation takes 2–7 days worldwide (e.g., China to the US: 3–5 days), making it ideal for time-sensitive projects. However, it is 3–5 times more expensive than sea freight, so it is recommended only for urgent needs.

Regulatory Compliance: The manufacturer ensures compliance with air cargo regulations, including labeling hazardous materials (if applicable) and providing a Shipper’s Declaration for Dangerous Goods (SDDG) if the cable’s materials (e.g., PVC Insulation) are classified as hazardous.

Physical Damage: Damage from accidents (truck collisions, ship grounding), natural disasters (hurricanes, floods), or improper handling (dropping drums during loading/unloading).

Loss or Theft: Coverage for complete loss of the shipment (e.g., stolen containers) or partial loss (e.g., missing drums).

Claim Process: If damage occurs, the customer must notify the manufacturer and insurance provider within 48 hours of receiving the shipment. The customer provides photos/videos of the damage, a copy of the delivery receipt, and a detailed damage report. The insurance provider assesses the claim within 5–10 working days and arranges for compensation (repair, replacement, or refund) based on the extent of the damage. The insurance premium is typically 0.3%–0.5% of the order value, which can be added to the total order cost or paid separately.

Order Confirmation: The sales team sends a formal order confirmation within 24 hours, outlining the product specifications (conductor size, sheath material, water depth rating), quantity, delivery date, and payment terms. The customer reviews and signs the confirmation to confirm agreement.

Production Scheduling: For standard configurations (e.g., 50mm² TPU-sheathed cable for shallow water), production begins within 3–5 working days. For customized configurations (e.g., deep-sea cables with stainless steel armour or integrated data wires), production takes 10–15 working days, as additional time is needed to adjust manufacturing equipment (e.g., extrusion dies for thicker sheaths) and test the customized design.

Quality Inspection and Packaging: After production, the cable undergoes a 1–2 day quality inspection (electrical, mechanical, and environmental tests). Once approved, the cable is packaged into drums/boxes and prepared for shipping. The manufacturer notifies the customer when the shipment is ready, providing details such as the number of drums, total weight, and shipping documents.

Pre-Delivery Notification: The logistics team sends a pre-delivery notification 3–5 days before the shipment arrives, including the estimated delivery date, time window (e.g., 9 AM–3 PM), and the name of the delivery driver/contact person.

Site Preparation Guidance: The manufacturer provides guidance on site preparation to ensure smooth delivery, such as:

Delivery Delay Management: If a delay occurs (e.g., due to logistics issues or production delays), the manufacturer notifies the customer immediately and provides a revised delivery date. The manufacturer also offers compensation for delays caused by its own negligence (e.g., late production), such as a 1% discount on the total order value for each day of delay (up to 10% maximum).

Quantity Verification: The customer checks that the number of drums/boxes matches the packing list. Any discrepancies (e.g., missing drums) must be noted on the delivery receipt and reported to the manufacturer within 24 hours.

Package Integrity Check: The customer inspects the drums/boxes for signs of damage (e.g., broken drum flanges, torn cardboard, water stains). If damage is found, the customer takes photos/videos as evidence and notifies the manufacturer and logistics provider within 48 hours (for insurance claims).

Product Specification Check: For a random sample of drums, the customer verifies the cable’s specifications (e.g., conductor size, sheath material) by checking the drum labels and comparing them to the order confirmation. If the specifications do not match, the customer can reject the shipment and request a replacement.

Acceptance Confirmation: If no issues are found, the customer signs the delivery receipt to confirm acceptance. The manufacturer sends a copy of the signed receipt to the customer for their records.

Standard Samples: 1m–5m lengths of the cable, suitable for laboratory testing (e.g., electrical performance, material composition) or visual inspection. Standard samples are available for all sheath materials (TPU/CSP), water depth ratings, and conductor stranding configurations.

Customized Samples: For customers with unique requirements (e.g., specific anti-fouling coatings, integrated data wires), customized samples can be produced. These samples typically take 7–10 working days to manufacture and are available in 5m–10m lengths.

Installation Trial Samples: 10m–20m lengths of the cable, designed for on-site installation trials. These samples allow customers to test the cable’s flexibility, ease of termination, and compatibility with existing equipment (e.g., submersible pumps, ROVs).

Submit Sample Request Form: The customer completes a sample request form, providing details such as:

Sample Quotation: For standard samples, the manufacturer provides the sample free of charge (the customer only covers shipping costs). For customized samples, the manufacturer provides a quotation (typically \(50–\)200, depending on the complexity of the customization) within 2 working days.

Payment and Shipping: For fee-based customized samples, the customer makes payment via bank transfer or online payment platforms (e.g., PayPal). Once payment is received, the manufacturer ships the sample via the customer’s preferred logistics method (e.g., DHL, FedEx) within 3–5 working days. A tracking number is provided to the customer for real-time shipment monitoring.

Certificate of Analysis (COA): Summarizes the results of tests conducted on the sample, including insulation resistance (≥1000MΩ·km), tensile strength of the sheath (≥18MPa), and hydrostatic pressure resistance (per the water depth rating).

Material Safety Data Sheet (MSDS): Provides information on the cable’s materials, including hazards, handling precautions, and disposal guidelines. This is particularly important for customers in industries with strict safety regulations (e.g., oil and gas, aquaculture).

Testing Guide: Includes instructions for conducting basic tests on the sample (e.g., measuring conductor resistance with a multimeter, checking sheath flexibility by bending the cable). For customers requiring third-party testing, the manufacturer can coordinate with accredited laboratories (e.g., SGS, TÜV) to conduct advanced tests (e.g., H₂S corrosion resistance, UV degradation) and provide test reports.

Pre-Installation Support: Before installation, the technical team provides guidance on:

On-Site Technical Support: For large-scale projects (e.g., offshore wind farms, oil rigs), the manufacturer can dispatch engineers to the customer’s site to provide hands-on support:

Remote Technical Support: For smaller projects or urgent issues, the technical team offers remote support via phone, email, or video call (e.g., Zoom, Microsoft Teams). The team can provide real-time guidance on troubleshooting (e.g., identifying the cause of a short circuit, recommending repairs for minor sheath damage) and can review photos/videos of the installation to provide feedback.

1-Year Warranty: For standard shallow-water cables (≤10m depth) with TPU or CSP sheaths and no armour.

2-Year Warranty: For medium-depth cables (10m–500m depth) with reinforced water barriers (copper tape) and optional GSWA.

3-Year Warranty: For deep-sea cables (≥500m depth) with stainless steel-reinforced barriers and heavy-duty GSWA.

Insulation breakdown due to poor XLPE quality.

Sheath cracking or peeling due to defective TPU/CSP material.

Conductor corrosion due to inadequate water barrier protection.

Improper installation (e.g., exceeding the minimum bending radius, using non-waterproof terminations).

Misuse (e.g., using a shallow-water cable in deep-sea conditions, exposing the cable to chemicals not specified in the MSDS).

External factors (e.g., anchor damage, marine life attacks, natural disasters).

Notify the Manufacturer: The customer notifies the manufacturer’s after-sales team within 7 days of discovering the defect, providing details such as the order number, batch number, date of delivery, and a description of the defect.

Provide Evidence: The customer submits photos/videos of the defect, a copy of the delivery receipt, and any test reports (e.g., insulation resistance test results) to support the claim.

Defect Assessment: The manufacturer’s technical team assesses the defect to determine if it is covered by the warranty. This may involve requesting a sample of the defective cable for laboratory testing (the manufacturer covers the cost of sample shipping).

Claim Resolution: If the defect is covered by the warranty, the manufacturer offers one of the following resolutions:

Maintenance Guidelines: A comprehensive maintenance manual, outlining:

Periodic Maintenance Services: For large-scale customers (e.g., offshore wind farm operators), the manufacturer offers annual maintenance visits, where engineers:

Lifecycle Management: The manufacturer provides guidance on end-of-life disposal of the cable, ensuring compliance with environmental regulations (e.g., recycling Copper Conductors, properly disposing of PVC insulation in accordance with EU WEEE directives).