Oxygen Content: ≤0.003% by weight, ensuring high purity and conductivity. This low oxygen level prevents the formation of copper oxides, which can degrade electrical performance over time.
Conductivity: 101% IACS (International Annealed Copper Standard) at 20°C, exceeding the conductivity of standard Copper Conductors (100% IACS). This high conductivity ensures efficient dissipation of fault currents to earth.
Resistance: ≤158 Ω/km for 32 AWG at 20°C, minimizing voltage drops in grounding circuits and ensuring effective current flow.
Stranding Configuration: 32 AWG conductors consist of 7 strands of 0.08mm diameter OFC wire, twisted in a concentric lay pattern with a lay length of 3–5mm. This stranding enhances Flexibility, allowing the wire to bend around tight corners with a minimum bending radius of 2mm (5x the conductor diameter).
Tensile Strength: ≥200 MPa for the Copper Strands, ensuring they can withstand the mechanical stress of installation and use without breaking.
Shield Material: Tinned copper strands (0.05mm diameter) to enhance corrosion resistance and solderability. Bare copper strands are also available as a cost-effective alternative for dry, indoor environments.
Braid Coverage: 85% as standard, with options for 70% (light protection) or 95% (heavy protection) coverage. Higher coverage increases EMI blocking capability but slightly reduces flexibility.
Braid Angle: 45° to balance coverage and flexibility, ensuring the shield remains intact during bending and routing.
Shield Resistance: ≤50 Ω/km for tinned copper braid, ensuring effective grounding of intercepted EMI signals.
FEP Insulation:
Thickness: 0.1mm
Temperature Rating: -65°C to 200°C
Dielectric Strength: ≥20 kV/mm
Chemical Resistance: Resistant to oils, solvents, and most chemicals, making it suitable for harsh industrial environments.
Thickness: 0.1mm
Temperature Rating: -30°C to 80°C
Dielectric Strength: ≥15 kV/mm
Cost-Effective: Provides a more economical option for general-purpose applications where extreme temperatures or chemicals are not a concern.
PTFE Insulation (Optional):
Thickness: 0.1mm
Temperature Rating: -200°C to 260°C
Dielectric Strength: ≥25 kV/mm
High Performance: Ideal for aerospace, defense, and high-temperature industrial applications.
2-Core:
Conductor: 2 x 32 AWG OFC strands
Overall Diameter: 1.2mm (FEP insulation) / 1.3mm (PVC insulation)
Weight: ~1.5 kg/km
3-Core:
Conductor: 3 x 32 AWG OFC strands
Overall Diameter: 1.4mm (FEP insulation) / 1.5mm (PVC insulation)
Weight: ~2.0 kg/km
4-Core:
Conductor: 4 x 32 AWG OFC strands
Overall Diameter: 1.6mm (FEP insulation) / 1.7mm (PVC insulation)
Weight: ~2.5 kg/km
Printed Circuit Boards (PCBs): 32 AWG 2-core wires are used to ground sensitive components such as microprocessors, sensors, and integrated circuits. The small size and flexibility allow for easy routing on densely packed PCBs, while the OFC conductor ensures low resistance grounding to prevent signal interference.
Consumer Electronics: Audio equipment, computers, and smartphones rely on these grounding wires to reduce noise and improve signal quality. The beige braided shield prevents EMI from affecting audio signals or data transmission, resulting in clearer sound and more reliable performance.
Medical Electronics: MRI machines, patient monitors, and lab instruments use 3 or 4-core wires to provide redundant grounding paths, ensuring safety and accuracy. The FEP insulation is resistant to sterilization chemicals, making it suitable for use in healthcare environments.
Ethernet and Data Networks: 2 or 3-core wires with 85% braid coverage are used to ground Ethernet cables and network equipment, reducing EMI that can corrupt data transmission. This is particularly important in high-speed networks (10Gbps and above) where signal integrity is critical.
Fiber Optic Transceivers: Grounding wires connect transceivers to ground busbars, preventing static buildup that can damage sensitive optical components. The 32 AWG size allows for integration into small form-factor transceivers.
Satellite and Radio Equipment: 4-core wires with 95% braid coverage provide robust EMI protection for satellite dishes, radios, and antennas, ensuring clear signal reception even in areas with high levels of RFI.
Programmable Logic Controllers (PLCs): 3-core wires ground PLCs and their associated sensors and actuators, isolating power-related noise from control signals. This improves the reliability of industrial automation systems and reduces downtime.
Motor Drives: Grounding wires connect motor drives to earth, dissipating fault currents and reducing EMI that can interfere with other equipment. The tinned copper shield resists oil and grease in industrial environments.
Robotics: The flexible 32 AWG Stranded Conductor is ideal for grounding robotic arms and grippers, which require frequent movement. The small bending radius allows for routing through tight spaces in robotic joints, while the braided shield protects against EMI from motor drives.
Aerospace Electronics: 4-core wires with PTFE insulation are used in aircraft avionics, providing grounding in extreme temperature environments (-200°C to 260°C). The OFC conductor ensures reliable performance at high altitudes, where electrical conductivity can be affected by low pressure.
Defense Systems: Radar, communication, and weapons systems use these grounding wires to meet strict EMI/EMC requirements. The customizable shield options allow for tailoring to specific military standards (e.g., MIL-STD-1553).
Control Panels: 3 or 4-core wires ground components in industrial control panels, preventing electrical noise from affecting sensitive instruments. The beige color makes it easy to identify grounding wires in complex wiring harnesses.
Heating and Cooling Systems: Grounding wires with FEP insulation are used in high-temperature heating systems, where they can withstand temperatures up to 200°C. The braided shield protects against EMI from motors and other equipment.
Production: OFC is produced using a special refining process that removes oxygen and other impurities, resulting in a purity of 99.99% or higher. This high purity ensures maximum conductivity and corrosion resistance.
Properties: OFC has a higher conductivity than standard copper, lower resistance, and better solderability. It is also more resistant to oxidation, ensuring long-term performance in harsh environments.
Stranding: The 7 strands of 0.08mm diameter OFC wire are twisted together to form the 32 AWG conductor. This stranding increases flexibility and reduces the risk of conductor breakage during bending.
Tinned Copper Strands: The shield is made from tinned copper strands (0.05mm diameter) to enhance corrosion resistance. The tin coating also improves solderability, making it easier to terminate the shield to ground.
Braid Construction: Strands are woven into a braid using a braiding machine, which controls the coverage, angle, and tension. The beige color is achieved by using pre-colored tinned copper strands or by applying a special coating after braiding.
Shield Attachment: The braided shield is connected to a drain wire (a single 32 AWG OFC strand) to facilitate grounding. The drain wire is twisted with the shield and terminated to a ground lug or busbar.
FEP: Fluorinated ethylene propylene is a high-performance fluoropolymer with excellent chemical resistance, high-temperature tolerance, and low dielectric constant. It is extruded over the OFC conductor using a precision extrusion process to ensure uniform thickness.
PVC: Polyvinyl chloride is a cost-effective insulation material with good electrical properties and flexibility. It is extruded over the conductor and cured to form a durable insulation layer.
PTFE: Polytetrafluoroethylene is a premium insulation material with exceptional high-temperature resistance and chemical inertness. It is applied using a paste extrusion process, making it suitable for small gauge wires like 32 AWG.
For applications requiring additional protection, an outer jacket made of PVC or FEP can be added. The jacket provides extra mechanical protection and can be colored to match the braided shield (beige) or customized to meet specific identification requirements.
Wire Drawing: OFC rods (8mm diameter) are drawn through a series of diamond dies to reduce their diameter to 0.08mm. This process ensures uniform wire size and surface finish.
Stranding: 7 strands of 0.08mm OFC wire are twisted together in a stranding machine. The machine controls the lay length (3–5mm) and tension to ensure a uniform, Flexible Conductor. The stranding process is monitored using cameras and sensors to detect any defects.
Preparation: The stranded OFC conductor is cleaned to remove any contaminants that could affect insulation adhesion.
Extrusion: The conductor is passed through an extrusion machine, where FEP, PVC, or PTFE insulation is applied. The extrusion die is designed to ensure a uniform insulation thickness of 0.1mm. For FEP and PTFE, the insulation is cured in an oven to set its properties.
Quality Control: The Insulated Conductor is checked for thickness, eccentricity, and surface defects using laser gauges and visual inspection systems.
Cabling: 2, 3, or 4 insulated conductors are twisted together in a cabling machine to form the core. The lay length is set to ensure the cores are evenly spaced and the overall diameter is consistent.
Binder Tape (Optional): A thin polyester binder tape is applied around the cabled cores to hold them together and provide a smooth surface for the braided shield.
Braiding: Tinned copper strands (0.05mm diameter) are woven around the cabled cores using a braiding machine. The machine controls the number of strands, braid angle (45°), and coverage (70–95%) to meet specifications.
Drain Wire Attachment: A 32 AWG OFC drain wire is twisted with the braided shield and secured using a small amount of adhesive or tape.
Shield Testing: The shield is tested for continuity and resistance to ensure it provides effective EMI protection.
If an outer jacket is required, the shielded core is passed through another extrusion machine, where PVC or FEP jacket material is applied. The jacket thickness is controlled to meet specifications, and the surface is printed with identification information (e.g., wire type, AWG size, manufacturer).
Electrical Testing: Each batch of wires is tested for conductivity, resistance, and dielectric strength to ensure they meet electrical specifications.
Mechanical Testing: Samples are tested for tensile strength, elongation, and flexibility to verify mechanical performance.
Shield Effectiveness Testing: The EMI shielding effectiveness is measured using a network analyzer, ensuring it meets the required attenuation levels (typically ≥60dB at 1GHz).
Environmental Testing: Wires are subjected to temperature cycling, humidity, and chemical exposure tests to verify performance in harsh environments.
Bulk Reels: For large quantities (1000m or more), wires are wound onto wooden or plastic reels. Wooden reels are sturdy and cost-effective, with flanges to prevent unwinding. They are available in sizes ranging from 300mm to 600mm in diameter, depending on the wire length. Plastic reels are lightweight and moisture-resistant, making them ideal for humid environments or international shipping.
Labeling: Each reel is labeled with essential information, including:
Wire type (customized grounding wire)
Core configuration (2, 3, or 4-core)
AWG size (32 AWG)
Conductor Material (OFC)
Shield type (beige braided tinned copper, coverage percentage)
Insulation material (FEP, PVC, or PTFE)
Length (meters)
Voltage rating (300V)
Standards compliance (UL 444, IEC 60228, RoHS, etc.)
Manufacturer name and part number
Batch number for traceability
Spools: For smaller quantities (10m, 50m, 100m), wires are wound onto plastic spools with a diameter of 100mm or 150mm. These spools are lightweight and easy to handle, making them suitable for retail or small-scale projects.
Cut Lengths: Custom cut lengths (from 1m to 50m) are available, packaged in sealed plastic bags with labels containing the same information as the reels. This option is ideal for prototyping or small production runs.
Plastic Wrap: Reels and spools are wrapped in a protective plastic film to prevent dust, dirt, and moisture from contaminating the wire. This also protects the braided shield from damage during handling.
Cardboard Boxes: For international shipping or storage, reels are placed in sturdy cardboard boxes with foam padding to prevent movement and damage. The boxes are labeled with handling instructions and warning symbols (e.g., "Fragile," "Keep Dry").
Manufacturers offer custom packaging options for bulk orders, including:
Branded reels or spools with the customer's logo and artwork
Custom label designs with specific information required by the customer
Specialized packaging for automated assembly lines (e.g., tape-and-reel packaging for PCB assembly)
Road Transport: For domestic shipments within a country, trucks with enclosed trailers are used to transport reels and spools. This provides protection against weather and road debris, ensuring the wires remain clean and undamaged. Smaller packages (cut lengths) can be shipped via courier services.
Rail Transport: For large quantities over long distances, rail transport is an efficient and cost-effective option. Reels are loaded into railcars and secured to prevent movement during transit.
Sea Transport: International shipments of bulk reels are transported by sea freight. Reels are packed into shipping containers, with dunnage (wooden blocks) and straps to secure them and prevent shifting. Humidity-absorbing packets are included to protect against moisture in containerized transport.
Air Transport: For urgent shipments or small quantities, air freight is available. Small spools and cut lengths can be shipped via air, with strict weight and size restrictions.
Reel Handling: Reels should be lifted using appropriate equipment, such as forklifts with reel handlers or cranes with slings. This prevents damage to the reel flanges and the wire inside. Reels should be moved vertically (with the flange faces horizontal) to avoid unwinding.
Spool Handling: Small spools can be handled manually, but care should be taken to avoid dropping them, which could damage the wire or the spool.
Avoiding Damage: Wires should not be dragged across rough surfaces, as this can damage the braided shield and insulation.
Temperature Control: During transportation, wires should be protected from extreme temperatures. FEP and PTFE Insulated Wires can withstand a wide range, but PVC-insulated wires should not be exposed to temperatures below -30°C or above 80°C for extended periods, as this can cause insulation cracking or softening.
Humidity Control: Moisture can damage the braided shield and promote corrosion. Sea and air shipments include humidity-absorbing packets, and enclosed transport vehicles are ventilated to prevent condensation.
Order Confirmation: Upon receiving an order, the manufacturer sends a confirmation within 24 hours, detailing the specifications (core count, insulation type, shield coverage), quantity, pricing, and estimated lead time. For custom configurations, a technical drawing is provided for customer approval before production begins.
Lead Times: Standard configurations (2-4 core, FEP/PVC insulation, 85% shield coverage) have a lead time of 5-7 business days. Custom options (e.g., PTFE insulation, 95% shield coverage, special colors) require 10-15 business days to allow for material sourcing and production adjustments.
Tracking Numbers: Once shipped, customers receive a tracking number via email or SMS, allowing them to monitor the shipment’s progress through the carrier’s online portal. Real-time updates include departure from the factory, arrival at regional hubs, and estimated delivery date.
Delivery Alerts: Automated notifications are sent 24 hours before delivery to ensure someone is available to receive the shipment. For large reels, customers can schedule delivery times to align with their receiving schedules.
Unpacking Guidelines: Customers are advised to inspect packages upon delivery for signs of damage (e.g., crushed reels, torn packaging). A checklist is included with each shipment to guide inspection:
Verify reel/spool integrity (no cracks or dents).
Check wire ends for fraying or shield damage.
Confirm labeling matches the order (core count, insulation type, length).
Damage Reporting: Any damage must be reported to the manufacturer and carrier within 48 hours, with photos documenting the issue. The manufacturer coordinates with the carrier for claims and arranges for replacements or refunds as needed.
Standard Samples: Free 1m samples are available for standard configurations (2-4 core, FEP/PVC insulation, 85% tinned copper shield). Customers can request up to 3 samples to compare options (e.g., FEP vs. PVC insulation).
Custom Samples: For specialized configurations (e.g., PTFE insulation, 95% shield coverage), samples are provided for a fee (\(30-\)50), which is credited toward a subsequent order of ≥1000 meters.
Request Submission: Samples can be requested via the manufacturer’s website, email, or phone, with customers specifying:
Core count and AWG size.
Insulation material (FEP, PVC, PTFE).
Shield type (tinned/bare copper, coverage percentage).
Intended application (to help recommend optimal configurations).
Shipping address and preferred carrier.
Turnaround Time: Standard samples ship within 2 business days; custom samples take 5-7 business days. Each sample includes a test report with key parameters (conductivity, shield resistance, dielectric strength).
Application Support: A team of engineers provides guidance on:
Selecting the right configuration (e.g., 3-core vs. 4-core for redundant grounding).
Installation best practices (e.g., terminating braided shields to avoid EMI leakage).
Compliance with standards (e.g., UL 444 for communication systems, MIL-STD-1553 for defense applications).
Troubleshooting: For performance issues (e.g., excessive EMI, insulation failure), engineers conduct root-cause analysis, often requesting photos or test data to recommend solutions (e.g., upgrading to 95% shield coverage).
Standard Warranty: 5-year warranty covering defects in materials and workmanship (e.g., insulation cracking, shield delamination under normal use). The warranty does not cover damage from improper installation, abuse, or exposure to conditions beyond rated limits (e.g., PVC insulation in temperatures >80°C).
Extended Warranty: A 10-year warranty is available for industrial and aerospace customers, including annual inspections to verify shield integrity and insulation performance.
Unused Returns: Unopened reels/spools can be returned within 30 days for a full refund (less shipping), with a 15% restocking fee for custom configurations.
Defective Replacements: Wires failing within the warranty period are replaced free of charge, with expedited shipping for critical applications (e.g., medical equipment downtime).
Customer Surveys: Post-purchase surveys gather feedback on:
Ease of installation (e.g., wire flexibility, shield termination).
Performance in application (e.g., EMI reduction, durability).
Packaging and delivery experience.
Product Enhancements: Feedback drives improvements, such as developing a more flexible 95% shield option or adding UV-stabilized jackets for outdoor applications.
In summary, wholesale manufacturer customized grounding wires—with their oxygen-free copper cores, beige braided shields, and 2-4 core 32 AWG design—deliver precision grounding and EMI protection for sensitive systems. From rigorous production processes to customer-centric logistics and support, every aspect is optimized to meet the unique demands of electronics, industrial, and aerospace applications. Whether for noise reduction in medical devices or EMI compliance in defense systems, these wires provide a tailored, high-performance solution backed by comprehensive service.
Hongtai Cable Technology Co.,Ltd
E-mail:export@qlcables.com
sales@qlcables.com
Tel/whatsapp:+86-18032066271
ADD:Xiaokou Industrial Development Zone, Ningjin County, Xingtai City,Hebei Province, China
Copyright © Hongtai Cable Technology Co.,Ltd Technical Support: Ronglida Technology
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