Pressure regulators can be selected based on the size of the pipe in the system. But they're not like on/off valves, more is involved. Sizing a pressure regulator is a bit more difficult than sizing some other types of valves, but it is not all that hard to do. In this article, we will share a guide for selecting the right Filter Regulator 

If the compressed air device has a “flow static” characteristic, then the pressure only needs to be held above the minimum required level at the end of an operation. For example, a cylinder is moved from one position to another to hold a piece in a clamp. In this case, the pressure needs to be adequate only when the clamping action takes place, with minimal flow, not while the cylinder is moving positions.

A “flow static” application is something that requires the minimum pressure to be maintained at the point of use at the same time as peak flow. An example of this might be a cylinder with a constant load that might need to stroke from one position to another in 0.5 second.

For the flow static application, smaller components can be used; it doesn’t matter much what pressure drop occurs in the filter regulator, as long as the proper pressure occurs at the end of the stroke to apply the required force.

For the flow dynamic application, careful design must take place to ensure the combined total of all the pressure drops across the filters, regulator, lubricator, supply hoses and connectors does not allow the pressure to fall below the minimum required pressure at the point of use.

One mistake commonly made is to assume an incorrect average flow per minute and wrongly size the components too small. Consider a flow dynamic load that strokes a cylinder with a volume of 0.1 cubic feet at a pressure of 60 psi, four times per minute at one half second per stroke. This load would consume 0.5 cubic feet of free air per stroke. Operating the cylinder one way 4 times per minute would consume about 2 cubic feet of air in one minute. If an FRL were sized for this flow an excessive pressure drop would occur. It must be sized for the dynamic flow.

The dynamic flow of the cylinder would be the flow rate in the half second operating time. Since the 0.5 cubic feet of free air flows in one half a second, the dynamic flow during the stroke would be 1 cubic foot per second (0.5/.5 second) or 60 cfm. Thus the flow requirement would be much higher, requiring larger components.

Like all compressed air components, each element of the FRL will have a pressure loss characteristic. You first need to know the characteristic of the end used (flow static or flow dynamic), the flow, and the minimum required pressure. Then you must know the minimum input pressure from your compressed air system. Then it is an exercise in mathematics in selecting the components that will result in proper end use pressure. Each component will have a pressure loss curve you can consult to find the pressure loss at your stated flow.

That's all information, if you want to know more information, please visit the professional Filter Regulator manufacturer https://www.nblida.com/product/air-treatment/