A Copper Alliance Member
- Applications
- Resources
- Find Suppliers of Copper
- Technical Reference Library
- Publications List
- Automotive
- Building Construction: Architecture
- Building Construction: Fire Sprinklers
- Building Construction: Home Builders' Marketing Materials
- Building Construction: Natural Gas
- Building Construction: Plumbing
- Electrical: Energy Efficiency
- Electrical: General
- Electrical: Power Quality
- Electrical: Telecommunications
- Industrial: Bronze Bearings
- Industrial: Cast Products
- Industrial: General
- Industrial: Machined Rod Products
- Industrial: Mold Alloys
- Properties / Standards
- Seawater
- Soldering / Brazing / Welding
- Special Publications
- Statistics / Directories
- Seminars, Workshops & Training
- Market Data
- Standards
- Properties
- Properties of Wrought and Cast Copper Alloys
- Properties of Copper
- Low Temperature Properties of Copper
- Cryogenic Properties of Copper
- Typical Uses of Copper Alloys
- Copper Compounds
- Microstructures of Copper Alloys
- Corrosion Protection & Resistance
- Fabrication Practices
- Powder Metallurgy
- Metallurgy of Copper-Base Alloys
- Questions?
- Consumers
- Education
- Environment
- Publications
- Newsletters
- Publications List
- Automotive
- Building Construction: Architecture
- Building Construction: Fire Sprinklers
- Building Construction: Home Builders' Marketing Materials
- Building Construction: Natural Gas
- Building Construction: Plumbing
- Electrical: Energy Efficiency
- Electrical: General
- Electrical: Power Quality
- Electrical: Telecommunications
- Industrial: Bronze Bearings
- Industrial: Cast Products
- Industrial: General
- Industrial: Machined Rod Products
- Industrial: Mold Alloys
- Properties / Standards
- Seawater
- Soldering / Brazing / Welding
- Special Publications
- Statistics / Directories
- About CDA
Industrial
- Copper Motor Rotor
- Casting Alloys
- Copper Alloy Molds
- Applications
- Benefits
- Comparison of Mold Alloy Properties
- Whirlpool Uses Copper Alloy Mold
- Technical Paper - Cooling Prediction
- Technical Paper - Getting Heat Out of the Mold
- Copper Core With Copper Chill Plate Runs Better Than Water In Steel
- Copper-Alloy Core Solves Warpage
- Copper-Alloy Cores Reduce Cycle Time
- Wear Research To Compare Copper Molds To Steel
- ANTEC Report - Use of Copper Alloys to Reduce Mold Condensation Problems
- ANTEC Report - Impact of Fines Separation
- ANTEC Report - Comparison of Various Hard Coatings
- ANTEC Report - Understanding the Source of Reduced Mechanical Properties
- ANTEC Report - Resistance to Erosive Wear
- ANTEC Report - Undercutting Mold Performance
- ANTEC Report - Minimization of Gate Wear
- Applications
- Bronze Sleeve Bearings
- Selecting Bronze Bearing Materials
- Electronic Connector Design Guide
- Mold Design Guidelines
Effect of Time and Temperature on Copper-Tin
Photo ©1998 AMP INC. Copper-tin intermetallic compounds form at the interface of the tin plate and the base metal, for all of the different processes used to tin copper alloy strip. With both time and temperature, the intermetallic grows to the surface, becomes oxidized, and can affect contact integrity.
Because Commercial Hot Dipped Tin already has some intermetallic compound at the surface when produced, its service life is likely to be the shortest. After three months in storage at summer temperatures, practically all of the surface could be compound.
Electrotinned products, relatively free of intermetallic when plated, offer longer service life. But after four weeks (without elevated temperature) about 25µ-in can be detected at the copper-tin interface. This too, will eventually grow to the surface. The growth rate of the intermetallic on Electrotinned is more rapid than for that on Air Leveled Tin and Reflow Tin (and Commercial Hot Dipped Tin). Their cast micro structures with big grains inhibit intermetallic growth at moderate temperatures. Longer service times are afforded (or thinner tins can be used for equivalent performance).
Intermetallic growth can be retarded by using a "barrier metal" (a metal that diffuses much, much, more slowly with the base alloy and the tin). Nickel has long been plated under gold to act as this diffusion barrier and it is similarly effective for tin plating. A barrier layer may significantly slow the diffusion of elements other than copper, for example, zinc (zinc oxides at the contact surface are resistive). A copper underplate will prevent or impede zinc from reaching the surface; 20µ-in is often used on Reflow Tin products. For brasses, 100µ-in of copper is effective. Copper underplate is not an effective means to prevent Cu-Sn intermetallic at the surface. Diffusion barriers are often used on Electrotinned and Reflow Tin. Incorporation of a barrier for Commercial Hot Dipped Tin and Air Leveled Tin would require a separate operation.
Beyond the Basics - Performance Over Time
- Overview of Stress Relaxation
- Stress Relaxation Tests
- Alloy Selection for Stress Relaxation
- Time Affects Stress Relaxation
- Temperature Affects Stress Relaxation
- Initial Stress Level Affects Stress Relaxation
- Orientation Affects Stress Relaxation
- Temper Affects Stress Relaxation
- Fatigue Strength
- Factors Affecting Fatigue Strength
- Interface Corrosion
- Stress Corrosion Cracking (SCC)
- SCC Susceptable & Resistant Alloys
- Tin Coatings
- Tin Whiskers
- Copper-Tin Intermetallic Compounds
- Effect of Time and Temperature on Copper-Tin
- Contact Resistance When Using Tin Coatings
- Friction When Using Tin Coatings
