The direct control valve
A direct flow control valve consists of an orifice for controlling the flow and a controlled surface that determines the size of the opening that flow can pass through, and thus determines the amount of flow passing through the valve.
- Advantage: such a control valve is relatively fast, cheap, and uses only little power to control the flow.
- The disadvantage here is that it can only handle limited pressures and flows.
Let’s take an electromagnetic valve as an example:
For a flow control valve, the force (F) needed to overcome to open the valve is determined by the orifice diameter size (d) and the pressure difference (Δp) over the valve , (F ~ Δp * ¼ d2). When either the pressure differential or the orifice diameter gets higher, the direct control valve will not open adequately due to this pressure force, which can be > 15 N for a 200 bar differential pressure over a 1mm orifice, pushing the valve shut.
An electromagnetic control valve can only exert a force of ca. 5N on its plunger. It could be a possibility to use a stronger coil, delivering a larger magnetic force. However, mass flow controllers often have a limited power supply and the amount of heat that is produced can become a problem as well. Resulting in a limited maximum flow, proportional to pressure and the diameter squared.
In summary, most direct flow control valves are not suitable for high flows, or to handle high differential pressures or absolute pressures due to these restrictions. The direct control valves could be used for low flows from 1mln/min up to approximately 50ln/min.
What alternatives do we have?
- Redesign the direct flow control valve for higher pressures
- Using a 2-phase valve, an indirect control valve
- Using a pressure compensated valve, to reach high flows at low pressures