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Properties and Overview of Copper Alloy Evanohm
Overview:
Copper Alloys are a critical component of modern industry, valued for their exceptional conductivity, corrosion resistance, and versatility. Combining copper with other elements such as zinc, tin, aluminum, or nickel creates a wide range of alloys, each tailored to specific applications. This adaptability has made copper alloys a cornerstone of traditional craftsmanship and cutting-edge engineering.
Production:
The production of copper alloys begins with the selection and combination of raw materials. Copper is melted with alloying elements in carefully controlled proportions to achieve the desired characteristics. The molten mixture is cast into ingots or billets, which are then processed into usable forms through rolling, extrusion, or forging techniques. Advances in metallurgical processes, including continuous casting and precision alloying, have further enhanced the quality and performance of copper alloys. Surface treatments, heat treatments, and other post-processing methods may also be applied to improve durability, machinability, or appearance.
Applications:
Applications of copper alloys span an extraordinary range of industries. In electrical engineering, copper’s unparalleled conductivity makes its alloys indispensable for wires, connectors, and electronic components. Brass, a prominent copper-zinc alloy, is widely used in plumbing, mechanical components, and decorative items due to its strength, corrosion resistance, and aesthetic appeal. Bronze, a copper-tin alloy, is revered for its durability and has applications in bearings, marine components, and artistic sculptures. Copper-nickel alloys, known for their excellent resistance to seawater corrosion, are commonly employed in shipbuilding, desalination plants, and offshore platforms. Additionally, copper alloys are used in coinage, musical instruments, and heat exchangers, where their combination of strength, malleability, and thermal conductivity proves invaluable.
The environmental benefits of copper alloys further enhance their significance. Copper and its alloys are highly recyclable, with a substantial proportion of production relying on recycled materials. This reduces the environmental impact of mining and extraction while conserving natural resources. Despite these advantages, challenges such as material cost and susceptibility to oxidation in specific environments drive ongoing research into protective coatings, advanced alloy formulations, and improved processing techniques.
Summary:
Copper alloys exemplify the fusion of tradition and innovation, offering properties that address the diverse needs of industries worldwide. From enhancing the efficiency of electrical systems to shaping timeless works of art, these alloys remain an essential material in both practical and creative domains. As sustainability and technological advancements continue to shape global priorities, copper alloys will remain vital in enabling progress and innovation across countless fields.
See a comprehensive list of electrical, mechanical, physical and thermal properties for Copper Alloy Evanohm below:
Electrical Properties of Copper Alloy Evanohm
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Mechanical Properties of Copper Alloy Evanohm
| Mechanical Property (Units) | Value |
|---|---|
| Copper Alloy Evanohm Compressive Strength (MPa) | ~800 |
| Copper Alloy Evanohm Ductile to Brittle Transition Temperature (°C) | Unknown |
| Copper Alloy Evanohm Fatigue Limit (MPa) | ~80 to 110 |
| Copper Alloy Evanohm Fracture Toughness (MPa·√m) | ~30 to 35 |
| Copper Alloy Evanohm Hardness Brinell | 120 to 160 |
| Copper Alloy Evanohm Hardness Rockwell | 70 to 80 HRB |
| Copper Alloy Evanohm Hardness Vickers | 130 to 170 |
| Copper Alloy Evanohm Heat Deflection Temperature (°C) | N/A - Not a Polymer |
| Copper Alloy Evanohm Modulus of Elasticity / Young's Modulus (GPa) | 160 |
| Copper Alloy Evanohm Percent Elongation (%) | 15 to 25 |
| Copper Alloy Evanohm Poissons Ratio | 0.33 |
| Copper Alloy Evanohm Shear Modulus (GPa) | 62 |
| Copper Alloy Evanohm Shear Strength (MPa) | 450 |
| Copper Alloy Evanohm Ultimate Tensile Strength (MPa) | 500 to 600 |
| Copper Alloy Evanohm Yield Strength (MPa) | 250 to 400 |
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Physical Properties of Copper Alloy Evanohm
| Physical Property (Units) | Value |
|---|---|
| Copper Alloy Evanohm Boiling Point at Atmospheric Pressure (°C) | Unknown |
| Copper Alloy Evanohm Chemical Composition (Element %) | Cu 54.0%, Ni 45.0%, Mn 0.8-1.0% |
| Copper Alloy Evanohm Cost ($/kg) | 50 to 60 |
| Copper Alloy Evanohm Density at 'Standard Temperature and Pressure' (kg/m3) | 8400 |
| Copper Alloy Evanohm Glass Transition Temperature at Atmospheric Pressure (°C) | N/A - Not a Polymer |
| Copper Alloy Evanohm Melting Point at Atmospheric Pressure (°C) | 1400 |
| Copper Alloy Evanohm Polymer Family | N/A - Not a Polymer |
| Copper Alloy Evanohm Refractive Index | Unknown |
| Copper Alloy Evanohm Specific Gravity | 8.4 |
| Copper Alloy Evanohm Viscosity at Melting Point (mPa·s) | 3 to 5 |
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Thermal Properties of Copper Alloy Evanohm
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