The optimal design strategy provides the best control, the lowest pressure for a given load, and will deliver maximum power to the load when the system is operated at the design point target.
Aiming for optimal design
The concept of optimal design is suggested in the second drawing. If we draw the speed-force operating envelope for a given system (one quadrant is displayed just to keep it simple), but then add a second vertical axis for the power to the load, the two curves shown are the result. If the actuator is operated at zero load force, no power will be applied to the load. Also, if the system operates at stall condition, no power will be delivered to the load. However, at all other load points between zero and stall, the power to the load is not zero. Logically, then, a unique point exists where the load power is maximized.
This can be derived mathematically by solving for the load power term, then differentiating and setting the derivative equal to zero. When solving for maximum power transfer, we learn that when the stall force is 11⁄2 times the design point force, it will be where maximum power to the load prevails. The control in such a system is excellent; proper sizing strategy has been employed, and, coincidently, the minimum possible pressure will have been found to work the load.
However, the point of maximum power to the load is not the point of maximum efficiency. Curiously, the efficiency always works out to 67% at the design point and increases as load force approaches the stall condition. It goes to 100% right at stall, an interesting, but useless fact.
An electrical analogy
In contrast, electrical systems engineers apply maximum power transfer strategy to electrical actuation. The process is called impedance matching, but because of the linear nature of Ohm’s law, the efficiency is only 50%. That means that when you have your home stereo system operating with an 8-V speaker connected to your amplifier with 8-V output impedance, and you are pumping out 50 W to your speaker, your amplifier is also consuming 50 W. It will get hot. If you had a hydraulic servovalve driving your speaker, you could deliver, say, 50 hp to your speaker, but you would be consuming only 25 hp in your valve, however, the audio volume might be a bit excessive!
Handbook introduces cylinder control