High frequency strands

High-frequency stranded wires are thin wires that are combined into a bundle. They consist of several individual wire cores that are twisted or braided together. High-frequency stranded wires are often made of copper, aluminum or other metals.

They are used in various areas and applications, for example in electrical engineering and electronics. There they serve as conductors for electrical current and are used in cables, plugs, switches and other electrical components.

High-frequency stranded wires are also used in telecommunications technology, for example for telephone and data lines. They are also often used in the automotive industry to make electrical connections.

Furthermore, high-frequency stranded wires are also used in model making, jewelry making and other crafts. In these cases, they are mostly used as a decorative element or to stabilize structures.

There are different types of high-frequency stranded wires, which have different properties depending on their composition and structure. Here are some of the most common types of high-frequency stranded wires:

1. stranded copper wires: Stranded copper wires consist of fine copper wires twisted into a strand. They have high conductivity and are often used in applications where a reliable electrical connection is required, such as in electrical engineering and electronics.

2. aluminum strands: Aluminum strands consist of aluminum wires twisted into a strand. They are lighter than copper strands and have good conductivity. Aluminum strands are often used in high-voltage cables and in applications where weight is an issue.

3. tinned stranded wires: Tinned strands are copper strands that are coated with a thin layer of tin. This gives them improved corrosion resistance and makes them easier to solder. Tinned strands are often used in electronics, e.g. for cable connections or in plugs.

4. silver strands: Silver strands consist of fine silver wires twisted into a strand. They have an even higher conductivity than copper strands and are therefore often used in applications where particularly good electrical performance is required, such as in audio cables or in measurement technology.

5. steel strands: Steel strands consist of steel wires twisted into a strand. They have a high tensile strength and are therefore often used in applications where high mechanical loads occur, such as in ropes or as reinforcement in rubber hoses.

These are just a few examples of different types of high frequency strands. There are other variations that can be used depending on the specific application and desired properties.

Stranded wires are produced by intertwining or twisting several thin wires. This is typically done by special machines that connect the wires together and twist them at the same time.

Different materials are used for the production of stranded wire, depending on the requirements of the application. Commonly used materials are copper, aluminum, steel and various alloys of these metals. The choice of material depends on factors such as electrical conductivity, mechanical strength, corrosion resistance and the intended use of the stranded wire.

High-frequency stranded wires offer various advantages compared to conventional wires:

1. flexibility: High-frequency stranded wires consist of many thin individual wires that are twisted together. This makes them significantly more flexible than solid wires. They can be bent, twisted and routed around corners more easily, making them ideal for applications where flexibility is required.

2. pliability: Due to their structure, high-frequency stranded wires are also very pliable. They can be bent into tight radii and curves without losing their conductivity or being damaged.

3. compactness: By using many individual wires instead of one solid wire, high-frequency litz wires can be produced in a smaller diameter. This means they take up less space and can be used in confined spaces or compact devices.

4. vibration resistance: Due to the twisting process, high-frequency stranded wires are also very resistant to vibrations. They are less susceptible to breakage and wear from vibration, making them ideal for applications in harsh environments.

5. current-carrying capacity: Due to the larger surface area created by the many individual wires, high-frequency stranded wires have a higher current-carrying capacity than comparable solid wires. This makes it possible to transport larger amounts of current without overheating or loss of power.
High-frequency stranded wires are more resistant to repeated bending and deformation than solid wires. As a result, they are more durable and last longer.

7. weight reduction: By using high frequency strands instead of solid wires, the overall weight of a component or application can be reduced. This is particularly important in areas such as aerospace or the automotive industry, where weight savings play a major role.

These advantages make high-frequency stranded wires an attractive option in many applications, including electronics, electrical engineering, telecommunications and many other industries.