11.1: Two Types of Resistance in a Hydraulic System

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Pump drawing fluid from a reservoir with no resistance on the opposite end. — Figure \(\PageIndex{1}\): When there is no resistance in a hydraulic system, there is no fluid pressure, just flow.

In hydraulic systems, there’s often a misconception that pumps create pressure. That’s not quite true. Pumps create flow, and pressure is the result of resistance to that flow. If a hydraulic system had no resistance—say, if it were pumping fluid into an open tank—then there would be no pressure at all, just flow.

In the real world, however, resistance is always present. This resistance is what creates the system pressure, and it comes from two main sources:

Frictional resistance from the fluid and system components
Resistance from the load being moved

Let’s take a closer look at each one.

Fluid Friction (Frictional Resistance)

Diagram of a pump drawing water from a reservoir, through a pipe, and back into the reservoir. — Figure \(\PageIndex{2}\): Frictional resistance causes a pressure increase upstream. The system must generate more pressure to keep fluid moving past that resistance .

As hydraulic fluid travels through pipes, valves, fittings, and other components, it encounters internal surfaces that slow it down. Even the smoothest components still create some friction. This is referred to as fluid friction, and it shows up as a pressure drop across each part of the circuit.

Key Factors Affecting Frictional Resistance

Component size and design – Narrow passages, sharp turns, or rough internal surfaces increase resistance.
Fluid viscosity – Thicker fluids (higher viscosity) have a harder time flowing and generate more resistance.
Flow rate – Higher flow means more friction due to increased turbulence in the fluid.

Each of these factors causes a pressure increase upstream of the component. The system must generate more pressure to overcome this resistance and keep the fluid moving.

While some friction is unavoidable, excessive friction wastes energy, turning it into heat. That heat buildup can reduce system efficiency and shorten component life. That’s why designers aim to minimize friction by properly sizing system components. For example, using larger-diameter hoses and fittings reduces resistance, just like using a wider straw makes it easier to drink a thick milkshake.

Load Resistance

The second major source of resistance is the load being acted upon by the actuator, usually a hydraulic cylinder or motor. When a cylinder pushes or lifts a load, the pressure needed to do that work depends on the force required and the piston area.

Pressure (P) = Area (A) x Force (F)

For example, to lift a load that requires 7000 psi with a known piston area, the system must generate at least that amount of pressure. However, this load pressure doesn’t exist in isolation. You still have to add the pressure drop from fluid friction.

Let’s look at a quick breakdown of total system pressure:

Load pressure: 7000 psi
Frictional pressure: 60 psi
Total pressure at the pump = 7060 psi

The 60 psi of friction might come from several points in the system. For example:

(7060 - 7020) = 40 psi drop due to one part (maybe a DCV)
(7020 - 7000) = 20 psi drop across another (possibly a pressure regulating device and the hoses of the system)
Combined: 40 + 20 = 60 psi total frictional resistance

This shows how system pressure is the sum of both the load and all frictional losses throughout the system.

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