Metal Composite Materials – WOBO Scientific Research New Materials One-Stop Service Platform

Zinc-Tin Alloy (ZnSn 10.0–50.0% Ni)

enerke — Thu, 24 Apr 2025 02:08:21 +0000

Product Overview
Zinc-tin alloy is a high-strength, corrosion-resistant material widely used in industries such as aerospace, automotive, and construction. By adding tin and nickel, the alloy enhances its mechanical properties, wear resistance, and corrosion resistance, making it ideal for demanding environments. Zinc-tin alloy offers an effective and cost-efficient alternative to expensive traditional alloys, providing both economic and social benefits.

Product Features

High strength and excellent corrosion resistance
Outstanding friction and wear resistance
Spark-free and non-magnetic, suitable for precision and safety-critical applications
Cost-effective and efficient production, adaptable to various processing methods
Good machinability and formability

Applications

Aerospace:Used in manufacturing spacecraft and aviation components, improving structural strength and durability
Automotive:Widely used in automotive parts to enhance performance and reduce weight
Construction:Applied in building materials and equipment to provide high strength and corrosion resistance
Mechanical Manufacturing:Ideal for making wear-resistant, low-friction parts, such as bearings, bushings, and gears
Electronics:Used in electronic devices to enhance material durability and safety

Zinc-Aluminum Alloy (ZnAl 2.0–5.0% Al)

enerke — Thu, 24 Apr 2025 02:07:03 +0000

Product Overview
Zinc-aluminum alloy is a material made with zinc as the base metal and aluminum as the alloying element. It offers excellent hardness, strength, and corrosion resistance. This alloy is widely used in industries such as aerospace, automotive, electronics, and construction. By optimizing its composition and performance, zinc-aluminum alloy meets the high mechanical and wear-resistance requirements of various applications.

Product Features

High hardness and strength
Excellent corrosion resistance, suitable for harsh environments
Excellent friction and wear resistance
Spark-free and non-magnetic, ideal for precision applications
Cost-effective with good machinability

Applications

Aerospace:Used for manufacturing high-strength, corrosion-resistant aerospace components
Automotive:Common in automotive parts, especially in high-wear applications
Electronics:Used to make wear-resistant, low-friction electronic components
Construction:Applied in building materials and equipment to improve structural durability and stability
Mechanical Manufacturing:Ideal for producing wear-resistant and low-friction parts, such as bearings, bushings, and gears

Zinc-Lithium Alloy (ZnLi 3.0–5.0% Li)

enerke — Thu, 24 Apr 2025 02:06:02 +0000

Product Overview
Zinc-lithium alloy is a material known for its excellent corrosion resistance, good thermal conductivity, and lightweight properties. It is widely used in the aerospace industry as a high-performance material, offering efficient performance in demanding environments. The unique physical properties of zinc-lithium alloy make it ideal for meeting both lightweight and durability requirements in high-tech fields like aerospace.

Product Features

Excellent corrosion resistance, suitable for harsh environments
Outstanding thermal conductivity, improving device efficiency
Lightweight, reducing overall structural weight
High mechanical performance with excellent friction and wear resistance
Spark-free and non-magnetic, perfect for high-precision and safety-critical applications

Applications

Aerospace:Used in spacecraft and aviation equipment, providing high performance, lightweight, and durable materials
Electronics:Applied in electronic components that require high thermal conductivity and low weight
Automotive:Used in manufacturing lightweight, corrosion-resistant automotive parts
Military:Ideal for making equipment and components that withstand high temperatures, pressure, and corrosive environments
Precision Machinery:Used in producing wear-resistant and low-friction parts, such as bearings, bushings, and sliders

Tellurium-Zinc Alloy (TeZn Te66.12Zn33.8%)

enerke — Thu, 24 Apr 2025 02:04:42 +0000

Product Overview
Tellurium-zinc alloy is a material primarily composed of tellurium and zinc. It offers excellent ductility and plasticity, along with strong corrosion resistance. This alloy is widely used in various high-tech fields, especially in optics, alloy manufacturing, and electronic devices. As a high-quality material, it exhibits unique advantages in specific applications.

Product Features

Excellent ductility and plasticity, easy to process
Good corrosion resistance, suitable for harsh environments
Maintains stable performance at high temperatures, with good heat resistance
Spark-free and non-magnetic, ideal for precision and safety-critical applications
Good machinability and formability

Applications

Optical Industry:Used to manufacture optical components, providing stable performance and excellent durability
Alloy Manufacturing:As part of alloy compositions, enhancing the overall properties of the alloy
Electronic Devices:Widely used in electronic components and devices to improve corrosion resistance and performance stability
Precision Machinery:Used to make precise and durable mechanical parts, such as bearings, bushings, and sliders

Copper-Rare Earth Intermediate Alloy (CuRe18)

enerke — Thu, 24 Apr 2025 02:03:30 +0000

Product Overview
Copper-rare earth intermediate alloy (CuRe18) is an alloy used to add rare earth elements to copper alloys during smelting. The addition of rare earth elements significantly enhances the properties of copper alloys, improving their high-temperature resistance, corrosion resistance, and oxidation resistance. This alloy is widely used to improve the strength, hardness, and ductility of copper alloys, making it suitable for high-demand engineering applications.

Key Features

The addition of rare earth elements enhances the high-temperature and corrosion resistance of copper alloys.
Improves the strength, hardness, and oxidation resistance of copper alloys.
Increases the alloy’s fluidity, making it suitable for precision casting.
Helps address the issues of copper’s susceptibility to burn-off, high melting point, and difficulty in melting.
Enhances the longevity and reliability of copper alloys.

Applications

Copper Alloy Smelting:Used for adding rare earth elements during the copper alloy smelting process to improve alloy performance.
Non-Ferrous Metallurgy:Improves the oxidation resistance and corrosion resistance of copper alloys during smelting.
Electronics Industry:Enhances the high-temperature performance of copper alloys, making them suitable for manufacturing electronic components.
Mechanical Manufacturing:Suitable for manufacturing mechanical components that require high strength and wear resistance.
Aerospace:Used in high-temperature and high-pressure environments to enhance the stability and durability of copper alloys.

Copper-Iron Intermediate Alloy (CuFe10)

enerke — Thu, 24 Apr 2025 02:02:08 +0000

Product Overview
Copper-iron intermediate alloy (CuFe10) is used for adding iron elements during the smelting of copper alloys. The addition of iron improves the strength, hardness, and corrosion resistance of the copper alloy. This alloy is widely used to enhance the mechanical properties of copper alloys, particularly in improving wear resistance and oxidation resistance.

Key Features

Increases the strength and hardness of copper alloys.
Enhances corrosion resistance and improves wear resistance.
Effectively improves the high-temperature performance and stability of copper alloys.
Addresses issues such as high melting points and burn-off in copper alloys.
Enhances the overall performance of copper alloys, extending their service life.

Applications

Copper Alloy Smelting:Used to add iron elements during the copper alloy smelting process.
Non-Ferrous Metallurgy:Increases the strength and corrosion resistance of copper alloys.
Mechanical Manufacturing:Used in the production of copper alloy components with higher strength and wear resistance.
High-Temperature Environments:Improves the stability and durability of copper alloys under high-temperature conditions.
Automotive and Engineering Machinery:Used for copper alloy components requiring wear resistance and high strength.

Copper-Arsenic Intermediate Alloy (CuAs30)

enerke — Thu, 24 Apr 2025 02:00:31 +0000

Product Overview
Copper-arsenic intermediate alloy (CuAs30) is an alloy used to add arsenic to copper alloys during smelting. The addition of arsenic enables the required chemical reactions within the alloy, enhancing its overall performance. Copper-arsenic alloy, as a special additive alloy, effectively addresses the problems of high melting point, burning, and difficulty in melting associated with pure copper, while also reducing segregation and optimizing the structure of the alloy. It is commonly used in the manufacturing process of other alloys, as a functional material such as deoxidizers, degassers, and desulfurizers.

Key Features

Combines high-purity copper with arsenic to enhance the alloy’s performance.
Solves the problem of poor melting of pure copper due to its high melting point.
Effectively reduces segregation, improving the uniformity of the alloy.
As an additive, it improves the mechanical properties of other alloys.
Can be used for functional applications in metallurgical processes such as deoxidation, degassing, and desulfurization.

Applications

Copper Alloy Smelting:Used to add arsenic during the production of copper alloys to improve their performance.
Non-Ferrous Metallurgy:Used as a deoxidizer, degasser, desulfurizer, and other functional materials to enhance the quality of alloys in the metallurgical process.
Electronics Industry:Used in the production of electronic components to optimize the electrical and mechanical properties of copper alloys.
Mechanical Manufacturing:Enhances the wear resistance and corrosion resistance of copper alloys, extending their service life.
Metal Metallurgy:Improves the stability and uniformity of alloys under high-temperature conditions.

Copper-Boron Intermediate Alloy (CuB5)

enerke — Thu, 24 Apr 2025 01:59:01 +0000

Product Overview
Copper-boron intermediate alloy (CuB5) is an alloy used for adding boron to copper alloys during smelting. The addition of boron significantly improves the hardness, strength, and wear resistance of copper alloys, while also providing excellent corrosion resistance. This alloy is suitable for improving the overall performance of copper alloys, especially in high-temperature and high-strength environments.

Key Features

The addition of boron enhances the hardness and wear resistance of copper alloys.
Improves the strength and corrosion resistance of copper alloys.
Increases the alloy’s fluidity, making it suitable for casting and precision manufacturing.
Used as an additive to optimize the properties of copper alloys.
Boron helps improve the oxidation resistance of copper alloys.

Applications

Copper Alloy Smelting:Used for adding boron to copper alloys during smelting to enhance the alloy’s performance.
Non-Ferrous Metallurgy:Improves corrosion resistance, wear resistance, and strength of copper alloys during the smelting process.
Electronics Industry:Suitable for manufacturing electronic components, enhancing the high-temperature and electrical performance of copper alloys.
Industrial Manufacturing:Used to produce mechanical components that require wear resistance and high strength.
Aerospace:Used in high-temperature environments to improve the performance and stability of copper alloys.

Copper-Manganese Intermediate Alloy (CuMn30)

enerke — Thu, 24 Apr 2025 01:55:46 +0000

Product Overview
Copper-manganese intermediate alloy (CuMn30) is a high-purity copper alloy primarily used to add manganese during the smelting of copper alloys. The addition of manganese improves the properties of the copper alloy, particularly enhancing its toughness. Copper-manganese alloys are typically used to improve the mechanical properties of the alloy, prevent the burning and melting issues associated with pure copper’s high melting point, and solve problems such as large density and easy segregation. It is widely used in non-ferrous metallurgy as an additive or functional material such as deoxidizers, degassers, and desulfurizers.

Key Features

Provides stable addition of manganese to copper alloys.
Improves the mechanical properties of copper alloys, especially enhancing toughness.
Effectively prevents burning and melting problems associated with the high melting point of pure copper.
Avoids segregation within the alloy, improving uniformity.
Widely used as a functional additive in deoxidation, degassing, and desulfurization processes in metallurgy.

Applications

Copper Alloy Smelting:Used to add manganese during the production of copper alloys, optimizing the mechanical properties of the alloy.
Non-Ferrous Metallurgy:Used as a deoxidizer, degasser, desulfurizer, and other functional materials to improve the quality of alloys in the metallurgical process.
Electrical Engineering:Used in the manufacture of high-strength, corrosion-resistant copper alloys for electrical equipment.
Mechanical Manufacturing:Enhances the toughness and durability of copper alloys in the production of mechanical components.
Electronics Industry:Used in the manufacture of electronic components and electrical connectors, improving performance and reliability.

Copper-Magnesium Intermediate Alloy (CuMg20)

enerke — Thu, 24 Apr 2025 01:54:26 +0000

Product Overview
Copper-magnesium intermediate alloy (CuMg20) is an alloy used for adding magnesium to copper alloys during smelting. The addition of magnesium effectively improves the mechanical properties of copper alloys, increasing their strength, hardness, and corrosion resistance. Copper-magnesium alloys can also enhance the castability and machinability of the alloy by altering its grain structure. This intermediate alloy is commonly used in non-ferrous metal metallurgy as an additive to improve alloy performance or as a deoxidizer, degasser, desulfurizer, etc., in the smelting process.

Key Features

Combines high-purity copper with magnesium to enhance the alloy’s strength and hardness.
Improves the alloy’s corrosion resistance and oxidation resistance.
Helps refine the grain structure of the alloy, improving castability.
As an additive, it significantly improves the mechanical properties of copper alloys.
Solves the issues of high melting points and segregation in copper alloys.

Applications

Copper Alloy Smelting:Used for adding magnesium to copper alloys during smelting to improve alloy performance.
Non-Ferrous Metallurgy:Used as a deoxidizer, degasser, desulfurizer, and other functional materials to optimize the smelting process.
Mechanical Manufacturing:Improves the mechanical properties and corrosion resistance of copper alloys, making them suitable for various mechanical components.
Casting and Molding:Enhances the castability of copper alloys and optimizes processing performance.
Electronics Industry:Enhances the durability and performance of copper alloys in electronic components.