Properties and Overview of Brass Alloy CZ108
Overview:
Brass Alloys are a cornerstone of metallurgy, known for their exceptional versatility, durability, and aesthetic appeal. A blend of copper and zinc, with occasional additions of elements like lead, tin, or aluminum, brass has been used for centuries in various industries. Its adaptability lies in the ability to tweak the proportions of its components, creating alloys tailored to specific requirements.
Production:
The production of brass alloys begins with carefully selecting and blending raw materials. Copper and zinc are melted together, often with precise adjustments to their ratios to achieve the desired properties. Other elements may be introduced during the process to enhance specific characteristics, such as machinability or corrosion resistance. Once melted, the molten brass is cast into ingots or billets, which can be further processed into sheets, rods, wires, or intricate shapes through rolling, extrusion, or forging.
Applications:
The applications of brass alloys are as diverse as their compositions. In plumbing and construction, brass is preferred for pipes, valves, and fixtures due to its corrosion resistance and strength. Its antimicrobial properties make it valuable in healthcare, where it is used for door handles, bed rails, and other high-contact surfaces. Brass's acoustic qualities have also made it the material of choice for musical instruments like trumpets and trombones, where its ability to produce rich, resonant tones is unparalleled. In marine environments, brass is highly sought after for its resistance to saltwater corrosion, finding use in ship fittings, propellers, and underwater components. Its conductivity and machinability make it indispensable in producing electrical connectors, terminals, and switches, while its aesthetic appeal ensures its presence in jewelry, architectural details, and decorative objects.
The enduring significance of brass alloys lies not only in their practical attributes but also in their sustainability. Brass is highly recyclable, with a significant portion of its production relying on recycled materials. This reduces the environmental footprint of brass manufacturing and aligns with modern efforts toward more sustainable industrial practices.
Summary:
brass alloys exemplify the ideal balance of beauty, strength, and functionality. Their ability to adapt to many applications, from functional components in machinery to decorative art pieces, underscores their importance in historical and contemporary contexts. As industries continue to innovate, brass remains a timeless material, contributing to technological advancements, design, and sustainability.
See a comprehensive list of electrical, mechanical, physical and thermal properties for Brass Alloy CZ121 below:
Electrical Properties of Brass Alloy CZ108
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Mechanical Properties of Brass Alloy CZ108
| Mechanical Property (Units) | Value |
|---|---|
| Brass Alloy CZ108 Compressive Strength (MPa) | ~550 |
| Brass Alloy CZ108 Ductile to Brittle Transition Temperature (°C) | Unknown |
| Brass Alloy CZ108 Fatigue Limit (MPa) | ~80 to 100 |
| Brass Alloy CZ108 Fracture Toughness (MPa·√m) | ~90 |
| Brass Alloy CZ108 Hardness Brinell | 70 to 100 |
| Brass Alloy CZ108 Hardness Rockwell | 40 to 70 HRB |
| Brass Alloy CZ108 Hardness Vickers | 80 to 120 |
| Brass Alloy CZ108 Heat Deflection Temperature (°C) | N/A - Not a Polymer |
| Brass Alloy CZ108 Modulus of Elasticity / Young's Modulus (GPa) | 100 to 110 |
| Brass Alloy CZ108 Percent Elongation (%) | 25 to 35 |
| Brass Alloy CZ108 Poissons Ratio | 0.30 |
| Brass Alloy CZ108 Shear Modulus (GPa) | 38 to 42 |
| Brass Alloy CZ108 Shear Strength (MPa) | 250 to 300 |
| Brass Alloy CZ108 Ultimate Tensile Strength (MPa) | 300 to 450 |
| Brass Alloy CZ108 Yield Strength (MPa) | 120 to 140 |
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Physical Properties of Brass Alloy CZ108
| Physical Property (Units) | Value |
|---|---|
| Brass Alloy CZ108 Boiling Point at Atmospheric Pressure (°C) | Unknown |
| Brass Alloy CZ108 Chemical Composition (Element %) | Cu 63%, Zn 37% |
| Brass Alloy CZ108 Cost ($/kg) | 5 to 7 |
| Brass Alloy CZ108 Density at 'Standard Temperature and Pressure' (kg/m3) | 8500 |
| Brass Alloy CZ108 Glass Transition Temperature at Atmospheric Pressure (°C) | N/A - Not a Polymer |
| Brass Alloy CZ108 Melting Point at Atmospheric Pressure (°C) | 900 to 940 |
| Brass Alloy CZ108 Polymer Family | N/A - Not a Polymer |
| Brass Alloy CZ108 Refractive Index | Unknown |
| Brass Alloy CZ108 Specific Gravity | 8.5 |
| Brass Alloy CZ108 Viscosity at Melting Point (mPa·s) | 3 to 6 |
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Thermal Properties of Brass Alloy CZ108
| Thermal Property (Units) | Value |
|---|---|
| Brass Alloy CZ108 Coefficient of Thermal Expansion (µm/m·K) | 20.5 |
| Brass Alloy CZ108 Emissivity Coefficient | 0.30 to 0.35 |
| Brass Alloy CZ108 Specific Heat Capacity (J/kg·K) | 380 |
| Brass Alloy CZ108 Thermal Conductivity (W/m.K) | 120 |
| Brass Alloy CZ108 Thermal Conductivity (BTU/h·ft·°F) | 69.38 |
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