What is your packing?

Hello,Our electrical cable is using electrical cable wheel for the packing, the wheel can be all steel wood, whole wood ,ect. We are using international standatd packing for different kinds ofcable, to ensure there will be no problem during

Which countries routinely use IEC cables?

Hello,(IEC) member countries cover more than 97% of the worlds population. The members are the national committees of the respective country, responsible for setting national standards and guidelines.

What's the quality assurance you can provide and how do you control the quality?

Hello,100% inspection on assembly lines. All controls, inspections, equipment, fixtures, total production resources and skills are inspected to confirm they consistently achieve the required quality levels.

What the out looking different of the Control cable and instrumentation cable?

Hello,The instrumentation cable core usual are pairing.Thanks.

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What is the difference in oxidation resistance between tin-plated copper conductors and bare copper conductors?

Difference in Oxidation Resistance Between Tin-Plated and Bare Copper Conductors

Tin-plated copper conductors exhibit significantly higher oxidation resistance than bare copper conductors, particularly in high-temperature, humid, or corrosive environments. Bare copper reacts with atmospheric oxygen and moisture to form copper oxide ( $\mathrm{CuO}$ or $\mathrm{Cu}_2\mathrm{O}$ ), which increases contact resistance and accelerates degradation. Tin-plating creates a sacrificial and protective barrier via a tin layer that undergoes passivation, forming a stable oxide film ( $\mathrm{SnO}_2$ ) that halts further atmospheric corrosion. According to ASTM B33 and IEC 60228, tinning preserves the solderability and electrical conductivity of the underlying annealed copper over an extended operational lifespan.

Technical Parameter Comparison

The following data matrix outlines the performance metrics of tin-plated versus bare copper conductors under various stress conditions.

Technical Parameter	Tin-Plated Copper Conductor	Bare Copper Conductor	Standard Reference
Oxidation Resistance	High (Forms stable $\mathrm{SnO}_2$ passivation layer)	Low (Formulates progressive $\mathrm{CuO}/\mathrm{Cu}_2\mathrm{O}$ scale)	ASTM B33 / ASTM B3
Max Continuous Operating Temp	Up to 150°C (Depending on insulation)	Typically limited to 100°C to prevent rapid oxidation	IEC 60502-1
Corrosion Resistance (Sulfate/Moisture)	Excellent (Resists sulfur-induced corrosion)	Poor (Prone to “green plague” or copper carbonate)	DIN VDE 0295
Long-term Solderability	Excellent (Maintained over extended storage)	Poor (Requires aggressive fluxing after oxidation)	IPC/EIA J-STD-002
Contact Resistance Over Time	Stable (Low intermetallic degradation)	Exponentially Increasing (Due to non-conductive oxide layer)	BS EN 60228

Mechanism of Atmospheric Degradation in Copper Conductors

Bare Copper Oxidation Kinetics

When exposed to ambient air, bare annealed copper undergoes a direct chemical reaction with oxygen. Initially, cuprous oxide ( $\mathrm{Cu}_2\mathrm{O}$ ) forms, followed by cupric oxide ( $\mathrm{CuO}$ ). This layer is porous and brittle. As electrical current flows, the localized $I^2 R$ heating accelerates the oxidation rate exponentially, leading to degradation of the electrical path and localized thermal runaway at termination points.

Tin Passivation Barrier

The application of a uniform tin layer via electroplating or hot-dipping creates a barrier typically 1 to 5 microns thick. Tin possesses a high affinity for oxygen, rapidly creating a microscopic, dense layer of tin dioxide ( $\mathrm{SnO}_2$ ). Unlike copper oxide, this passivation layer is non-porous and structurally stable, completely sealing the underlying copper from oxygen migration and galvanic corrosion.