GEA's extensive process knowledge and continuous research delivers the most efficient mixers and blenders. We offer a wide range of technical solutions and process options to ensure the efficient mixing and blending of liquids, powders and granules for a broad scope of industries and applications.
Our range of high-performance mixers and wide range of capacity options means you can choose a machine that exactly matches your processing requirements. From food, beverage and dairy applications to chemical, personal care and pharmaceutical ones, whether batch or continuous, GEA not only understands mixing technology, we also have a unique understanding and know-how of the entire process, based on many years of experience and hundreds of successful installations.
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The BATCH FORMULA® MIN High Shear Mixer is a semi-automatic, compact mixing system for dairy, beverage, plant-based beverage and liquid food applications.
The BATCH FORMULA® PRO High Shear Mixer is available with and without vacuum and therefore optimizing mixing and process times. Typical applications include dressings, soups and sauces, beverages, dairy and home & personal care products.
GEA’s modular DIBATCH batch mixing platform has been designed to offer quality, flexibility and efficiency for manufacturers of beverages such as soft drinks, energy drinks and juices.
GEA DICON® continuous in-line blending concept for the beverage industry.
GEA DICON® Continuous In-Line Blenders for HPC & Chemicals
The impact of global warming is increasingly apparent all over the world. Towns and cities everywhere face the same challenge: providing their communities with reliable, affordable, sustainably sourced heat. GEA spoke with an expert in the field, Kenneth Hoffmann, Manager, Heat Pumps at GEA Heating & Refrigeration Technologies, about tackling global warming faster.
Something caught Farmer Tom's eye. Instead of another product demo, GEA showcased innovations via AR. That's only the start of GEA's interactive digital farm.
GEA scientists are working with researchers at the Graz University of Technology to configure a homogenization process and technology that turns eucalyptus pulp into 3D-printed, organic structures mimicking human veins, arteries and other tissues.