Versatility the key to valve usage
Manufacturers suggest you consider four main criteria in selecting a pneumatic directional control valve: valve function,
type of valve actuation, installation arrangement, and the flow capacity (or valve size) needed for the actuator. The first
three are pretty well defined by the application. The fourth — valve size — also is defined by the application, but it
takes some work to dig out an accurate figure. Most pneumatic system designers know that the main configurations (how the
valve’s internal pathways are connected) for directional control valves are 2/2-, 3/2-, 5/2-, and 5/3- way. The first number
represents the number of ports, and the second number deontes the number of discrete positions. Likewise, designers can
easily determine whether actuation will be manual or mechanical, by solenoid, by pilot pressure, or by a combination of
solenoid and pilot pressure. Installation options cover a little more ground, but most encompass stand alone (in-line or sub
-base) or manifold mounting. Wiring can be plug-in or hardwired, and serial communication makes wiring simpler, faster, and
much less expensive. Avoid pressure drop In conjunction with the first three main criteria, the most important decision —
from the viewpoint of economical operation — is matching the valve’s flow capacity to the application requirements. Air
flow usually is measured in cubic feet or liters per minute. A component’s flow coefficient (a unit-less number designated
as CV) is an indication of the amount of resistance to flow that the component presents. Flow coefficients for air valves are
available from their manufacturers. All devices that conduct air resist flow to some degree. As a result, Air valves abound
in versatility as air flows through a restriction, its pressure drops. The less resistance, the lower the pressure drop, also
called ΔP. The amount of pressure drop across the restriction increases exponentially as flow increases. Any pneumatic
device — even a fitting or run of tubing — will affect the flow rate in a system. In rapidly cycling applications, a few
extra inches of tubing or the wrong fitting can mean the difference between a circuit that works as designed and one that
misses the mark. For this reason, valve flow ratings alone cannot predict the flow rate through a system or branch. All
components must be considered. Size doesn’t matter In the past, sizing a valve simply involved matching the port size of an
actuator to the valve. Today, however, it no longer is even suggested as the way to size an air valve. Technological
advancements now allow physically smaller valves to pass much greater flows, so port size has become even less significant.
Smaller valves tend to have several advantages over larger valves. In general, these include: faster shifting, less leakage,
lower power consumption because smaller solenoids can move lighter internal parts, greater mounting flexibility because valve
footprints are smaller, and lower cost. But small size isn’t the only advancement of today’s air valves. Serial
communication, innovative designs, and proprietary configurations give designers a much wider variety of products to choose
from . We present a small sampling of this variety on gthis and following pages.
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