RF Shield Kits for Ubiquiti Networks AirMAX Gear

 

The RF Shield Kits market report offers a thorough study of the market, including the market size, forecast analysis, growth graph over the last few years, and Covid-19 impact analysis. The recent outbreak of COVID-19 has led to large-scale uncertainties in the market, but this study provides valuable insights into the current situation. Its forecast analysis is based on historical data and industry models. Hence, it is a must-read for market players.

RF Armor's Durable Shield Kits Extend the Life of Your Ubiquiti Networks(R) airMAX (TM) Gear

The RF Armor shield kit for Ubiquiti Networks airMAX gear reduces unwanted signal interference to ensure a clear, distorted signal. Made of marine-grade aluminum, it also protects the plastic from harsh environments and UV rays. The shielding helps to improve channel planning and sustain air rates, extending the life of your airMAX gear.

RF Armor's MicroShield is an RF shield Kits that eliminates the need for external shields and enhances performance by reducing board space and overall cost. It is also compatible with any over-molded packaging technology. It's available for POLARIS(r) 3 TOTAL RADIO. RF Armor will demonstrate its industry-leading portfolio of products and technologies at the 2008 GSMA Mobile World Congress in Barcelona.

RF Armor's NanoBridge and UltraDura v3 kits protect your airMAX (TM) gear from interference. Unlike other shield kits, NanoBridge features two bullets without antenna that are connected when space is 250 meters or more apart. And thanks to their ultra-durable shield, you can be sure your gear will remain free of RF noise for years.

RF Armor's Shielding Kits are specially designed to reduce unwanted RF energy as well as provide weather protection to Ubiquiti's extensive range of outdoor radios and antennas.#RFShieldingKits #circuits #electronics pic.twitter.com/KEA6cofXnK

— Joddie Marshall (@joddie_marshall) May 9, 2022

Copper is the Most Preferred Material for Radio Frequency Shielding

Aside from its natural resistance to oxidation, copper is the most preferred material for RF shielding. Copper is easily manufactured and can be shaped into almost any shape required. As a result, copper-based RF shields are easier to install than other materials. And, since copper is non-ferrous, it's not likely to corrode in the environment, making it an excellent choice for shielding applications.

Aside from being highly conductive, copper also has excellent resistivity to oxidation and corrosion. As a result, it's the most reliable material for shielding applications. Copper is used in many types of equipment, including medical and personal computers. Copper can also be alloyed with other metals to create more corrosion-resistant products. One copper alloy is alloy 770, which is a combination of copper, nickel, zinc, and other elements. This material resists corrosion and is especially useful for shielding applications involving medium to high-frequency frequencies.

Other materials that are used for RF shielding include elastomeric materials such as silicone rubber and fluorosilicate. Foil shields are thin and can be damaged when stretched. Spiral shields are another type of RF shielding material. They're easy to install but are vulnerable to tearing and can develop discontinuities. However, they are the least expensive option and are the most preferred material for shielding.

RF Armor's Series 81 RF Shielding Reduces Collocation Interference

RF Armor's Series 81 line of RF shielding provides superior performance and value while adhering to Universal Building Codes. These shielding products protect critical wireless equipment by reducing front-to-back noise ratios and greatly reducing foreign/hostile interference. They protect both Rockets and Jumpers and improve performance and reliability with a lower noise floor and higher sustained air rates.

One of the most common types of RF interference is at 81 kHz. The Bruker Biospec system uses a switching power supply that generates 81 kHz RF, which is a significant contributor to the interference. In addition, the flood histogram is reduced, and scintillator elements near the edges of the detector array are impossible to resolve. The use of carbon fiber tubing, meanwhile, only protects against high-frequency RF and is not a viable solution for lower-frequency RF interference. Carbon fiber tubing does not shield against eddy currents and cannot be used to shield against high-frequency RF.

Another design criterion is the thickness of the outer copper shield. For Figure 3, we added 10 layers of copper shielding. After that, the shielding was unchanged. The thicker the copper shield, the less interference is passing through it. This is because the voltage across the outer shield varies, creating a potential difference between it and the PET module, which is grounded in the inner shield. The potential difference is large enough to cause significant interference in the detector.