Make the most of GEA hygienic valves to secure your lead in the dynamic market. Our valves adapt to your process and your product, not the other way round. There are no limits to your product ideas and demands. With ideally suited solutions, you can seize every opportunity to make a profit in your market.
Double-seat mixproof valves provide the shut-off of incompatible media at pipe intersections. Developed by Otto Tuchenhagen, the founder of GEA’s hygienic valve technology range, mixproof valves to this day deliver crucial benefits for safe and secure applications, e.g. in the case of cleaning agents in pipes carrying products.
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The easy solution for CIP feeds: GEA FLOWVENT Double-seal valves can be applied as efficient alternatives for secure separation of incompatible products within CIP systems or gas blocks.
State-of-the-art for your secure applications: GEA FLOWVENT Mixproof valves are used for the hygienically safe shut-off of incompatible media at pipe intersections.
24 / 7 PMO Valve® describes double-seat valves that have been authorised for use in PMO-regulated systems, where seat lifting occurs to clean the leakage chamber while the other pipeline is carrying product.
VARIVENT® mixproof divert valves are used for distributing liquid in pipelines, i.e. for distributing a liquid from one pipeline into two others, in which case one of the two pipelines must be shut off from the outlet line with a mixproof function.
GEA Valve process matrix
GEA VARIVENT® Mixproof valve type D
GEA VARIVENT® Mixproof valve type MX
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.