VARIVENT® and ECOVENT® single-seat valves are used for hygienic applications. The valves are characterized by their ease of operation and flexibility. To avoid pressure surges, individual variants in the VARIVENT® modular system are designed for different flow directions.
In the case of the simple shut-off, there is only one seal in the one-piece valve disc, which separates the pipelines. Therefore, we do not recommend to use single-seat valves for separating "hostile" media. In practical use, these valves are often used as emptying or drainage valves or for shutting off a bypass line. Frequently, these types of valve are also used as dosing valves.
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The master tool for all changeover functions: GEA FLOWVENT Divert valves are used for easy changeover solutions in hygienic applications.
The key to guiding your process flow: GEA FLOWVENT Shut-off valves are used for easy shut-off solutions in hygienic applications.
VARIVENT® single-seat divert valves are used for simple shuttle functions in hygienic applications. The valves are characterized by their ease of operation and flexibility. The individual variants are designed for different flow directions.
VARIVENT® single-seat valves are used for simple shut-off in hygienic applications. The valves are characterized by their ease of operation and flexibility. To avoid water hammers, individual variants in the VARIVENT® modular system are configured for different flow directions..
GEA VARIVENT® Divert valves - Product merging and distribution
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.