# Pneumatic Basics: Indirect Control

in STEMGeeks6 months ago (edited)

### 1. Introduction

Indirect control allows actuation of either single-acting or double-acting cylinder by an intermediate control valve and specifically used for large cylinder or cylinders operating at high speed. In direct control, cylinders are actuated indirectly by a final control valve which can handle large quantity of air. In the case of pilot operated valves, a signal input valve either actuated manually or mechanically is used to generate the pilot signal for the final control valve. The working pressure passing through the final control valve depends on the force requirement. Indirect control as permits processing of input signals. In this text, we present a solution for the following problems:

1. A single acting cylinder is to clamp a component when a pushbutton is pressed. As long as the push button is activated the cylinder is to remain in the clamped position. If the push button is released, the clamp is to retract. The single-acting cylinder must be retracted or extended with
50% of the input air pressure.

2. A double-acting cylinder is to extend when a push button is operated. Upon release of the push button the cylinder is to retract. The double-acting cylinder must must be retracted or extended with 50% of the input air pressure.

The solution provided in the text are for indirect control of single-acting and double-acting cylinder. In FluidSim, the solution is evaluated if it yields the correct response. In the next section, the pneumatic circuit and simulation result is presented.

### 2. Method and Result

Figure 1: Indirect control of single and double-acting cylinder

For the single-acting cylinder, a pneumatically actuated 3/2 way directional valve was used, as shown in Figure 1. For the double-acting cylinder, we used a pneumatically actuated 5/2 way valve to do the indirect actuation of the cylinder. Hence we assumed that the cylinder is of large capacity, the actuation can not be done by a single push button 3/2 way directional valve.

Figure 2: Push button is pressed (single-acting).

Figure 3: Push button is released. (single-acting)

When PB1 is pressed as shown in Figure 2, the normally closed 3/2 way DCV with push button shifted to open position that allows air pressure to pass through it. The air flows at the actuations port of DCV1 so that DCV1 opens and allows air to flow. In this case, the air builds up at the cylinder causing the cylinder to extend. Eventually, when PB1 is released, the spring return in DCV1 automatically shifts the control valve to initial state causing the air flow to be interrupted. Hence there are no air intake in the cylinder, the single-acting cylinder returns to retracted position.

Figure 4: Push button is pressed (double-acting).

Figure 5: Push button is released. (double-acting)

In Figure 5, Port 2 of DCV1 has air pressure to sustain the retracted position of the double-acting cylinder. This happen when PB1 is released or not pressed. When PB1 is pressed as shown in Figure 4, the flow of air in the 5/2 way directional valve (DCV1) shifted from port 2 to port 4. This allows air to build up at the extending port of the cylinder. This is made possible when the PB1 is pressed and it shifted to open position at which the air passes through it. The one-way flow control valve in the circuit is provided to ensure that the retraction or extension of the cylinder is paced at 50% of its normal speed or response.

Furthermore, the circuit is called a memory circuit because it uses a 5/2 way double pilot memory valve. 5/2 way valve can remember the last signal applied in terms of the position of the spool in the absence of reset springs, thus memorizing or storing the pneumatic signal. Double piloted 4/2 way valve also can be used as memory valve.

### 3. Conclusion

This circuit is suited for large single cylinder sand cylinders operating at high speeds. The final control valve is actuated by normally closed 3/2 way directional valve with push button which handle large quantity of air. When the PB1 is pressed, 3/2 way DCV with push button shifted from normally closed state to an open state and actuates the final control element (DCv1) which is in between the cylinder and PB1. When the push button is released, the actuation at DCV1 is released causing the DCV1 to return to its initial state. The signal pressure required can be around 1-1.5 bar. The working pressure passing through the final control valve depends on the force requirement which will be around 4-6 bar. Indirect control as permits processing of input signals. Single pilot operated valves are rarely used in applications where the piston has to retract immediately on taking out the set pilot signal.

### 4. Reference

[1] Pneumatic Basic Level. online access

[2] Pneumatic Advanced Level. online access

(Note: All images and diagram in the text are drawn by the author (@juecoree) except those with separate citation.)

If your are Interested in Pneumatic Basics, you can read the other posting:
1. Pneumatic Basics: Direct Control. (Online access on hive.blog or on Steemgeeks)

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