Advanced Graphene Applications

Vor-ink™ CX911 is an electrically conductive ink designed specifically for spray coating. This product adheres to coated papers, PET, and a variety of other substrates. Vor-ink™ retains conductivity after repeat flexing and offers excellent adhesion and abrasion resistance.

https://www.vorbeck.com/s/Vor-Ink-CX911-PIS_2018.pdf

Vorbeck Vor-coat coatings are a line of graphene-based EMI shielding products. Vor-coat coatings are designed to work with conventional industrial coating, painting, and spraying processes. They are easily applied to a variety of surfaces and shapes and has excellent flexibility. Vor-coat harnesses the power of graphene (a sheet of carbon a single atom thick), which has exceptional electrical conductivity, thermal properties, strength, and flexibility. Graphene-based Vor-coat can be applied using standard industrial coating processes to generate thin and very flexible cured coatings . Vorbeck has extensive experience using graphene sheets to fine tune the electrical properties and mechanical performance of Vor-coat products to meet a wide range of commercial requirements. We have shown that thin coatings of Vor-coat can attenuate electromagnetic transmissions at a broad range of frequencies. Vor-coat can be used to shield rigid and flexible substrates and has proven e ective in demanding use cases (e.g. medical devices) in which form-factor and environmental constraints has made other solutions infeasible.

https://www.vorbeck.com/s/2023_Vorbeck_EMI-Shielding-Coatings.pdf

In order to improve reception and increase data speeds, we have created a flexible printed S-Band antenna. Due to their thin and conformal nature, they can be incorporated into a variety of products such as clothing or fabrics worn by the user. They can also be utilized to reduce visual signature, weight and power consumption in land, sea and air vehicles. They are an easy-to-install option for fixed infrastructure assets as well. Multiple antennas can be deployed in high-performance arrays to create omnidirectional coverage and MIMO communications.

In order to improve reception and increase data speeds, we have created a flexible printed 900 MHz antenna. Due to their thin and conformal nature, they can be incorporated into a variety of products such as clothing or fabrics worn by the user. They can also be utilized to reduce visual signature, weight and power consumption in land, sea and air vehicles. They are an easy-to-install option for fixed infrastructure assets as well. Multiple antennas can be deployed in high-performance arrays to create omnidirectional coverage and MIMO communications.