Blog

With the rapid advancement of technology, conductive fabric is playing an increasingly important role in the electronics field. Conductive fabric combines the flexibility of traditional textiles with the conductivity of metals, offering innovative solutions for electronic products and smart devices.

In today's rapidly advancing electronic technology era, optimizing and enhancing the performance of electronic products has become key to industry competition. SMT conductive foam gaskets, as an excellent electronic material, plays a crucial role in enhancing the performance of electronic products through its robust performance and wide application range. SMT conductive foam significantly enhances electronic product performance in the following ways

FOF conductive fabric gaskets, also known as Fabric over Foam gaskets, are shielding materials made by covering non-conductive foam with conductive fabric plated with metals like copper and nickel. This combination endows FOF conductive fabric gaskets with a range of excellent properties, such as EMI protection, electromagnetic wave absorption, flame resistance, good conductivity, excellent resilience, and breathability. As a result, FOF conductive fabric gaskets have found widespread applications across multiple fields.

As electronic devices become more widespread and complex, electromagnetic interference (EMI) issues are becoming increasingly prominent. Selecting the right EMI components is crucial to effectively address this problem. Here, Konlida Precision Electronics will guide you on how to choose the right EMI components to ensure the normal operation and stable performance of your devices.

5G communication electromagnetic waves include two frequency bands, FR1 and FR2. FR1 ranges from 450MHz to 6GHz, while FR2 spans 24.25GHz to 52.6GHz, classified as millimeter waves. Due to the rapid attenuation of these waves in the air, it is necessary to employ ultra-dense networking methods for continuous network coverage. In the future, small and micro base stations will be deployed in crowded areas. To protect human health from electromagnetic radiation, it is crucial to implement electromagnetic shielding for base stations. This can be achieved using efficient electromagnetic shielding materials that absorb or reflect electromagnetic waves, thereby reducing radiation exposure to humans.

With the rapid advancement of technology, the consumer electronics industry demands increasingly higher performance standards. In particular, traditional SMT conductive elastic gaskets have become inadequate for specific applications in electromagnetic shielding and conductive connectivity. Leveraging profound material research capabilities, Konlida has successfully developed a low-pressure, high-resilience conductive foam, bringing a revolutionary solution to the consumer electronics industry.

Conventional conductive foam is single-piece typesetting, and the layout position requirements are not high.

This is a patch of conductive silicone foam that can be attached to a PCB using the SMT process. It has good electrical conductivity and excellent elasticity after reflow soldering and can be used as an EMI shielding ground or as an alternative to mechanical antenna shrapnel. At the same time, when the whole machine is subjected to external impact force, the product has a buffering function to avoid damage to other components by the impact force.

Electromagnetic shielding is designed to prevent high-voltage field strength interference on components. The principle is to use shielding to minimize the distributed capacitance between the interference source and the base, thereby reducing the interference's impact.

5G communication utilizes electromagnetic waves in two frequency bands: FR1 and FR2. FR1 ranges from 450MHz to 6GHz, while FR2 ranges from 24.25GHz to 52.6GHz, falling under the millimeter wave category. Electromagnetic waves in the FR2 band decay rapidly in air, necessitating ultra-dense networking for continuous coverage. Future deployments will include small and micro base stations in crowded areas.

Electromagnetic shielding is essential to prevent interference from high electric field strength on components. The design principle of electromagnetic shielding involves using a shield to minimize the distributed capacitance between the interference source and the base, thereby reducing the impact of the interference source on the base.