The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

This is a legacy product. Please contact us for the latest version.sales@ocaire.com, DIGITAL FLOW SWITCH, INSTRUMENTATION, PFD DIGITAL FLOW SWITCH, 2X, PFD NO SIZE (MISC.

This is a legacy product. Please contact us for the latest version.sales@ocaire.com, DIGITAL FLOW SWITCH, INSTRUMENTATION, PFD DIGITAL FLOW SWITCH, 2X, PFD NO SIZE (MISC.

SMC offers a variety of digital flow switches. Series PF2A for air, PF2W for water, PF2D for deionized water and chemicals. Flow rate setting and monitoring are possible with the digital display. Integrated and remote type displays are available for different types of application. Water resistant construction is used conforming to IP65 protection.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.

The standard air cushion utilizes a floating cushion seal to eliminate piston rod bouncing. The cushion volume has been elevated permitting about 30% more allowable kinetic energy absorption. The port and captive cushion adjustment valve are located on the same side of cap for heightened access.