This product is a CV/TFR-CV 0.6/1kV single-core copper conductor power cable, available in sizes from 95mm² to 300mm². Featuring XLPE insulation and thermosetting elastomer (TFR) sheath, it offers excellent electrical performance, heat resistance and mechanical strength, suitable for fixed installation in medium-low voltage distribution systems, particularly ideal for industrial applications requiring high current-carrying capacity and reliability.

This product is a 0.6/1kV single-core power cable with a copper conductor and cross-linked polyethylene (CV) insulation, suitable for fixed installations and power distribution systems. Available in various cross-sectional areas, including 300mm², 240mm², 185mm², 150mm², 120mm², and 95mm², it offers excellent electrical performance and heat resistance, widely used in industrial, construction, and infrastructure power transmission.

Our Aluminum Cable Torsade, available in configurations 416, 425, and 4*35, is engineered for high-performance overhead applications. Featuring single-core stranded copper conductors, these cables blend the conductivity of copper with the structural stability required for overhead power transmission.​ The cables are insulated with a multi-layer system combining XLPE (Cross-Linked Polyethylene), PE (Polyethylene), and PVC (Polyvinyl Chloride), ensuring superior protection against environmental stressors. XLPE provides excellent thermal resistance and dielectric strength, PE enhances flexibility and moisture resistance, while PVC offers robust UV and abrasion protection—making the cable suitable for harsh outdoor conditions.​ Designed with a torsade (twisted) structure, the cables deliver enhanced mechanical stability, reducing sagging and improving resistance to wind-induced vibration over long spans. This twisted design also minimizes electromagnetic interference, ensuring efficient power transmission for residential, commercial, and industrial overhead networks.​ Compliant with international standards, our Aluminum Cable Torsade offers a reliable solution for overhead distribution, combining durability, flexibility, and cost-effectiveness. Ideal for utility projects, urban electrification, and industrial power lines, it ensures consistent performance with minimal maintenance.

Aster Single Core Cable Insulated Prc 54.6mm2 Stranded Alloy Conductor for Overhead Construction XLPE PVC PE Copper Aluminum​ English Summary​ The Aster Single Core Cable Insulated Prc 54.6mm² is a high-performance solution engineered for overhead construction, featuring a stranded alloy conductor that balances strength and conductivity. Available in both copper and aluminum variants, this cable caters to diverse project needs—copper for superior conductivity (98% IACS) and aluminum for lightweight efficiency (61% IACS).​ Its 54.6mm² cross-section delivers a current capacity of 130A, making it ideal for medium-load overhead applications like rural electrification and industrial feeder lines. Insulation options (XLPE, PVC, PE) enhance versatility: XLPE withstands -40°C to 90°C for extreme climates, PVC offers cost-effective UV protection, and PE excels in moisture resistance, ensuring durability in wetlands or coastal areas.​ Designed for easy installation, the stranded conductor enhances flexibility, reducing fatigue during spanning (up to 45 meters). Compliant with IEC 60502 and local standards, it aligns with SEO keywords such as "stranded alloy overhead cable," "54.6mm² insulated conductor," and "XLPE/PVC/PE cable for construction," providing a reliable, adaptable choice for modern overhead power networks.

In medium-voltage power distribution networks, the 10kV voltage level is a key link connecting substations and distribution stations. The 10kV Single Core Overhead Cable (Aluminum Conductor, XLPE Insulated, 16 mm²) has become an ideal choice for urban and rural medium-voltage distribution lines, industrial park power supply dedicated lines, and power transmission in remote areas, thanks to its core advantages of "high-efficiency conductivity, reliable insulation, and adaptability to medium-voltage scenarios". Its design fully considers the electrical performance requirements of medium-voltage overhead environments and complex outdoor conditions. Through material selection and structural optimization, it achieves the comprehensive value of "low loss, anti-aging, and easy installation", and can effectively meet the multiple requirements of medium-voltage distribution systems for safety and stability, long-term durability, and cost-effectiveness.​ In terms of material and structural design, the cable adopts a core structure of "16 mm² aluminum conductor + XLPE insulation", and each component is accurately optimized for the characteristics of medium-voltage overhead scenarios. The conductor is made of high-purity aluminum with a purity of ≥99.5%, manufactured through a concentric stranding process. The stranding lay length is strictly controlled between 12-16 times the outer diameter of the conductor. This design not only improves the flexibility of the conductor, facilitating bending and installation between poles (such as crossing roads and avoiding obstacles) but also enhances fatigue resistance. It can withstand mechanical stresses caused by wind vibration and temperature alternations (-40℃ to 90℃) in long-term outdoor environments, preventing conductor breakage or deformation. Compared with copper conductors of the same specification, aluminum conductors reduce material costs by 40%-50%, and their density is only 27% of that of copper. The weight of a 16 mm² aluminum conductor cable per kilometer is about 30% of that of a copper conductor cable, significantly reducing the load-bearing pressure on poles and towers, and lowering the investment in infrastructure such as poles and brackets in the project. It is particularly suitable for large-scale medium-voltage overhead line laying.​ The insulation layer is made of cross-linked polyethylene (XLPE), which forms a three-dimensional network molecular structure through chemical cross-linking. Its performance is far superior to ordinary polyethylene and is the core of ensuring medium-voltage power supply safety: Firstly, it has excellent electrical insulation performance, with a breakdown field strength of over 26kV/mm, far higher than the requirements of the 10kV voltage level. It can effectively isolate current leakage between the conductor and the outside world, avoiding short circuits and ground faults in medium-voltage lines due to insulation failure, and ensuring the stable operation of the distribution system. Secondly, it has outstanding heat resistance, with a long-term allowable operating temperature of up to 90℃ and a short-term overload temperature of up to 130℃ (duration ≤5 seconds). It can cope with short-term large current impacts during peak summer electricity consumption or equipment startup, delaying the insulation aging rate. Thirdly, it has extremely strong weather resistance, capable of withstanding UV radiation, rain erosion, and acid rain corrosion, avoiding cracking and embrittlement of the insulation layer, and extending the cable's service life to more than 25 years (the service life of ordinary PE-insulated medium-voltage cables is about 15 years). At the same time, XLPE insulation has excellent mechanical strength, with a tensile strength of 16MPa and wear resistance more than twice that of ordinary PE, which can reduce external damage during construction and installation, and lower later operation and maintenance costs.​ In terms of electrical performance, the current-carrying capacity and loss characteristics of the 16 mm² aluminum conductor are fully adapted to the needs of medium-voltage distribution: at a working temperature of 90℃, the continuous current-carrying capacity of the conductor can reach 85A, which can meet the medium-voltage power supply needs of small and medium-sized industrial parks and multiple distribution stations; the DC resistance of the conductor at 20℃ is ≤1.83Ω/km, far lower than the upper limit of industry standards, with low current transmission loss, which can reduce power waste in medium-voltage lines and improve the overall efficiency of the distribution system. In addition, the capacitance and inductance parameters of the cable have been optimized, which can effectively suppress voltage fluctuations and electromagnetic interference in medium-voltage lines, ensuring the stable operation of precision equipment (such as industrial production machinery and intelligent distribution terminals).​ In terms of application scenarios, the cable's adaptability accurately covers the core fields of medium-voltage distribution: In urban and rural medium-voltage distribution lines, its lightweight feature facilitates upgrading and laying on existing poles without large-scale replacement of poles, reducing grid transformation costs, and the weather resistance of XLPE insulation can adapt to diverse urban and rural climates (such as rainy in the south, cold in the north, and high humidity in coastal areas). In industrial park power supply dedicated lines, the current-carrying capacity of the 16 mm² conductor can meet the production power needs of small and medium-sized factories, and the chemical corrosion resistance of XLPE insulation can resist mild industrial waste gas and dust pollution around the park, avoiding premature aging of the insulation layer. In power transmission in remote areas, the low-loss characteristics of the cable can reduce power waste during long-distance transmission, and the cost advantage of aluminum conductors can reduce the overall investment in power grid construction in remote areas, contributing to universal power access.​ From the perspective of cost and operation and maintenance, this cable shows significant comprehensive advantages. In addition to the direct material cost advantage brought by aluminum conductors, the long-term durability of XLPE insulation further reduces the full-life cycle cost—its anti-aging performance reduces the frequency of cable replacement (the number of replacements during the life cycle is only 2/3 of that of ordinary PE-insulated cables), and the insulation failure rate is low, reducing the annual operation and maintenance inspection cost by about 30%. At the same time, the cable strictly complies with the national standard GB/T 14049-2018 "Overhead Insulated Cables for Rated Voltage of 10kV" and the international standard IEC 60502-2, and meets high industry standards in key indicators such as conductor DC resistance, insulation resistance, and dielectric loss, ensuring that the safety and stability of medium-voltage power supply are not sacrificed while controlling costs.​ In conclusion, the 10kV Single Core Overhead Cable (Aluminum Conductor, XLPE Insulated, 16 mm²) has become an efficient solution in the field of medium-voltage overhead power distribution with its scientific material combination, excellent electrical performance, and scenario-based design. It can not only meet the core needs of medium-voltage distribution systems for safety, stability, and durability but also reduce project investment through cost optimization and low operation and maintenance characteristics, which is of great significance for promoting the upgrading of medium-voltage distribution networks and ensuring the reliability of urban, rural, and industrial power supply.

The Single Core 16mm² Aerial Bundle Cable (ABC) stands as a specialized solution in overhead power distribution, engineered to balance efficiency, durability, and safety for low to medium load applications. This cable integrates a high-purity aluminum conductor, cross-linked polyethylene (XLPE) insulation, and a polyethylene (PE) sheath, forming a robust structure tailored to withstand diverse environmental conditions while ensuring reliable power transmission. At the core of this cable is a 16mm² aluminum conductor, crafted from high-purity aluminum (minimum 99.5% purity) often alloyed with trace elements like magnesium or silicon to enhance tensile strength and corrosion resistance. The stranded design of the conductor—composed of multiple thin aluminum strands twisted concentrically—optimizes flexibility, allowing for easier installation across poles or along irregular routes. With a current-carrying capacity of approximately 70–85A at 30°C ambient temperature, the 16mm² cross-section strikes a practical balance, making it suitable for applications such as residential power supply, street lighting, and small-scale commercial establishments where moderate power demands are typical. Aluminum’s inherent lightweight property (approximately 2.7g/cm³) reduces structural stress on support poles, minimizing the need for heavy-duty infrastructure and lowering installation costs compared to copper alternatives. Encasing the aluminum conductor is a layer of cross-linked polyethylene (XLPE) insulation, a key feature that elevates the cable’s performance. XLPE is renowned for its exceptional thermal stability, enabling the cable to operate continuously at temperatures up to 90°C and withstand short-circuit conditions of 250°C for up to 5 seconds—critical for withstanding sudden load spikes or transient faults. This insulation also boasts a high dielectric strength (≥20kV/mm), ensuring minimal power loss during transmission and reducing the risk of electrical leakage, even over extended spans. Additionally, XLPE is highly resistant to water treeing, a common issue in humid environments that can degrade insulation over time, making the cable suitable for regions with high rainfall, coastal areas, or tropical climates. Its chemical inertness further protects against degradation from industrial pollutants, UV radiation, and ozone, extending the cable’s service life to 20+ years with minimal maintenance. Overlaying the XLPE insulation is a polyethylene (PE) sheath, which serves as a secondary protective barrier. PE is chosen for its flexibility, impact resistance, and resistance to environmental abrasion. This sheath shields the XLPE insulation from physical damage during installation—such as scratches from tree branches or contact with pole hardware—and from long-term wear caused by wind-driven debris, temperature fluctuations, or wildlife interference. The PE sheath also enhances UV resistance, complementing the XLPE’s inherent stability to ensure the cable retains its structural integrity even under prolonged exposure to sunlight. Available in black (standard) or colored variants for phase identification, the sheath simplifies installation and maintenance by allowing easy visual differentiation of conductors in bundled configurations. The single-core design of this 16mm² ABC cable offers distinct advantages in versatility. While it can be deployed individually for low-power single-phase applications (e.g., connecting a single residential unit to the grid), it is often bundled with other single-core cables of the same or complementary sizes to form multi-conductor ABC systems. This modularity allows utilities and contractors to customize configurations based on specific needs—for example, combining multiple 16mm² cables to support three-phase power for small commercial complexes or pairing with larger conductors to balance load distribution. The lightweight and compact profile (typically 8–10mm in outer diameter, including insulation and sheath) further facilitates installation in space-constrained areas, such as urban alleyways, dense residential neighborhoods, or rural regions with heavy vegetation, where clearance from obstacles is limited. Safety is a paramount feature of this ABC cable. Unlike traditional bare conductors, the fully insulated and sheathed design eliminates the risk of accidental contact with live parts, reducing the potential for electric shock, short circuits, or wildlife-related outages—common hazards in overhead networks. This makes the cable compliant with stringent safety standards, including IEC 60502-1 and ASTM B230, ensuring its suitability for use in populated areas. The combination of XLPE and PE also provides flame-retardant properties, slowing the spread of fire in case of accidental damage and enhancing overall network resilience. In terms of performance, the 16mm² cable delivers consistent efficiency across diverse operating conditions. Its low electrical resistance (≤1.15Ω/km at 20°C) minimizes power loss, ensuring that a high percentage of transmitted energy reaches the end user. This efficiency is particularly valuable in rural electrification projects, where long transmission spans are common, and energy waste must be minimized. The cable’s mechanical robustness—including a minimum bending radius of 10× its outer diameter—allows for flexible routing without compromising performance, while its resistance to corrosion ensures reliability in harsh environments, from coastal salt spray to industrial pollution. In summary, the Single Core 16mm² Aerial Bundle Cable with aluminum conductor, XLPE insulation, and PE sheath embodies a harmonious blend of materials and design, making it a versatile and reliable choice for modern overhead power distribution. Its balance of current capacity, durability, and safety addresses the needs of residential, commercial, and rural applications, while its modular design and ease of installation offer practical benefits for utilities and contractors. As global demand for efficient, safe, and cost-effective power infrastructure continues to grow, this cable stands as a critical component in building resilient and adaptable electrical networks.