Parker Hannifin has released its P2H IO-Link node, an addition to the company’s H Series ISO valve platform. Designed with IO-Link connectivity in mind, the P2H node provides a robust means of connecting H Series valves to the IO-Link network, thus saving total system and installation costs in comparison to the use of Ethernet or hard wiring. In addition, the P2H IO-Link node is safe-power capable, meaning auxiliary valve power can be supplied by a safety device in support of the European Machinery Directive.
P2H IO-Link node brings a general purpose industrial valve into the IO-Link portfolio, and yet maintains the ability to mix flow sizes on a Universal manifold base. The P2H IO-Link node complements Parker’s other IO-Link products focused on reducing complexity and cost at the machine, while supporting the simple diagnostics principles of smart factory and Industry 4.0 concepts.
Ideal for markets such as general industrial, automotive, materials handling, steelmaking, packaging and plastics, the P2H IO-Link node is a 24 output module, available in both Class A with a 7/8” power IN/Out connection for an independent auxiliary power supply – an industry first for an IO-Link valve device – or a Class B version with power and communication over a single five-pin M12 connector. It provides local diagnostic input data such as voltage monitoring, temperature warnings and communication error via the network. This functionality simplifies diagnostics and supports predictive maintenance strategies.
With its strong glass-filled PBT housing, the node offers weld-spatter resistance, UV protection and flame retardant properties. As a result, P2H is ideal for applications such as vehicle body welding and assembly processes. Further typical uses include systems for the application of adhesives and sealants, end of arm tooling (EOAT), riveting, blow moulding machines and case erectors. In terms of configuration, up to 24 solenoid addresses can be accommodated per manifold mixing HB, HA, H1 and H2 valve sizes thanks to the H Universal manifold design.