Robolux multi-port diaphragm valve reduces pipework by switching multiple flows
The revolutionary Robolux multi-port diaphragm valve promises cost saving, space saving and intelligent multi-port membrane characteristics – ideal for ultra-pure installations in food and beverage, chemical and pharmaceutical applications.

Hygienic processing applications place high demands on the reliability and cleanability of production facilities. Common challenges – such as corrosion in pipe systems, valve manifolds and tank installations in different pharmaceutical, chemical and biotech facilities for example – can be reduced, thereby reducing costs and improving plant availability simply by using multiport valves and multiport-based manifolds. Multi-port solutions, such as the Robolux diaphragm valve, were developed with exactly this type of high-purity installation in mind.
Compact multi-port diaphragm valve
The stand-out feature of the patented Robolux valve is that two independent process switching functions can be achieved with one membrane. This reduces the installation space requirement, eliminates T-adapters and minimises the overall number of valves and membranes required. The multi-port membrane valves were designed for high-purity installations and make it possible to design complex systems that are considerably more compact than those using conventional fluid control valves.
The design is also intended to minimise the internal volume and produce no dead flow zones, which results in a number of advantages. In addition to improved flow and evacuation properties, both cleaning and changeover of the interfaces for the manufacture of other products is easier and faster, with less wastage of expensive chemicals and ingredients.
This technology makes it possible to replace two traditional shut-off diaphragm valves and, at the same time, eliminate all dead legs and one tee-piece with one single valve. When combined with reduced installation and commissioning costs, the Robolux valve delivers a number of crucial advantages to process control within hygienic applications.
Robolux offers 100% cleanability and decentralised control
Bürkert can test clean cycles and provide 100% reliability on the flow properties and cleanability of the complete valve by using a riboflavin test rig. As part of a factory acceptance test, we are currently the only manufacturer of fittings and valve interfaces in the world that own and operate such a test rig. In hygienic applications where CIP/SIP are operated, it is essential to be able to ensure the cleaning cycle is both effective and efficient; criterion that we can completely fulfil and demonstrate.
As part of the concept to decentralise valve control systems, the Robolux valve can also now be combined with our ELEMENT control head to provide a complete process solution which is compatible with the entire valve product range. The valves at field level can be equipped with all the required automation components including pilot valves, electrical feedback units and optical status indicators. By integrating an AS interface as a field bus interface, the entire range of advantages of this approach can be fully utilised. All that is required for power supply, feedback and communication is a two-wire line connecting the PLC with up to 62 valves.
The new decentralised automation concept can provide a viable and extremely compact alternative to the use of central switching cabinets by integrating all the required automation functions in the control heads themselves. This provides considerable savings in installation costs and also provides commissioning and maintenance engineers with an instant indication of the status of each valve, which reduces the amount of time required for installation and trouble-shooting. The IP67 ELEMENT control head is compatible with a wide range of process control valves from Bürkert, ensuring greater plant standardisation across the board.
If you wish to talk to the Bürkert team about an application, please call us on +44 (0)1285 648720 or drop us an email at sales.uk@burkert.com.