Bernoullis Equation in Hydraulic Design

When designing hydraulic circuits, whether it’s for a tracked military vehicle, a heavy press line or a forestry arm, something which will often require consideration is how pressure behaves when flow conditions change. This is where Bernoulli’s equation becomes a valuable part of the hydraulic design process.

The Bernoulli equation connects the dots between fluid pressure, flow velocity and elevation. Based on Bernoulli’s principle it’s a simplified version of the conservation of energy applied to fluid mechanics.

What Is Bernoulli’s Equation?

The Bernoulli equation is based on the principle of conservation of energy and applies to a moving fluid under specific conditions. It tells us that the total pressure in a fluid flow, made up of pressure energy, kinetic energy and potential energy - stays constant along a streamline, assuming no work is added or lost and there's no friction.

The most common form of Bernoulli’s equation used in hydraulics:

P/ρg + v²/2g + z = constant

Where:

• P = static pressure of the fluid
  
  
• ρ = density of the fluid
  
  
• v = velocity of the fluid
  
  
• g = acceleration due to gravity
  
  
• z = elevation above a reference level
  
  

This form of the equation is valid for steady, incompressible, non-viscous fluid flow along a streamline.

Understanding Bernoulli’s Equation: Pressure, Velocity and Elevation

Each term in the Bernoulli equation corresponds to a different form of energy per unit weight of the fluid:

• Pressure Head - the pressure energy stored in the fluid
  
  
• Velocity Head - kinetic energy of the fluid due to flow velocity
  
  
• Elevation Head - potential energy due to elevation
  
  

The equation implies that an increase in one form must be balanced by a decrease in another. For example, as flow velocity increases, pressure decreases in a region of lower pressure, keeping total energy constant.

Using the Bernoulli Equation in Hydraulic System Design

In real-world hydraulics, engineers apply the Bernoulli equation to understand how a fluid’s velocity, density, and pressure interact within a system, particularly in mobile and industrial sectors. The equation can be applied to determine how pressure changes in hydraulic components, such as pipe reducers, elbows and control valves.

Mobile Equipment Example:

A construction machine lifting a load with a hydraulic ram might show a pressure drop in the return line when retracting at speed. Using the Bernoulli equation, the engineer can assess the difference in pressure caused by increased fluid speed in narrowed sections.

Industrial Press Systems:

In industrial presses, understanding the dynamic pressure versus static pressure can prevent uneven stroke movement. The form of Bernoulli’s equation helps evaluate how flowing fluid responds to varying loads.

Energy Sector Example:

Renewable energy setups often involve fluid flow at varying heights. The elevation head term in the Bernoulli equation is critical in sizing pumps for vertical transfer lines in ground source systems.

Bernoulli Principle vs. Continuity Equation

The Bernoulli principle works alongside the continuity equation, which is another key rule in fluid mechanics. The continuity equation states:

A₁v₁ = A₂v₂

Where A is the cross-sectional area, and v is the flow velocity. This tells us that if pipe diameter decreases, velocity of the fluid must increase which, based on Bernoulli’s law, causes a decrease in pressure.

This is seen in fittings like venturi blocks, where the Bernoulli effect is used intentionally to create a region of lower pressure for metering or suction.

When Bernoulli’s Equation Needs Modification

The equation is often used as a quick estimation tool but it makes a few assumptions:

• No friction (inviscid flow)
  
  
• Constant density (incompressible fluid)
  
  
• Steady fluid flow
  
  
• No pumps or turbines doing work
  
  
• Flow is along a single streamline
  
  

In real hydraulic systems, these conditions are seldom fully met. So, Bernoulli’s equation can be modified to include terms for head loss, typically using the Darcy-Weisbach equation. This allows for more accurate analysis, particularly in long pipe runs, turbulent zones, or systems with many bends and fittings.

Applications of Bernoulli’s Equation in Hydraulics

Let’s go through some real-world applications of Bernoulli’s equation in different hydraulic sectors.

Mobile Sector Applications

• Tracked military vehicles: Calculate pressure drop across cooling lines and actuation systems.
  
  
• Railway hydraulics: Balance system flow in braking or suspension applications.
  
  
• Harvesting machinery: Predict the effect of speed on arm extension or retraction.
  
  
• Construction equipment: Optimise hose diameter for stability and speed during boom operations.
  
  

Industrial Sector Applications

• Presses and machine tools: Use Bernoulli’s equation to assess flow rate limits.
  
  
• Process and food machinery: Ensure consistent fluid pressure in fast-paced systems.
  
  
• Printing: Fine control of air flow and fluid speed in ink supply systems.
  
  

Energy and Utilities

• Renewables: Manage pressure compensation in variable-height storage tanks.
  
  
• Waste and recycling: Control high-pressure circuits in balers and compactors using pressure difference predictions.
  
  

In every case, the equation applied early in the design helps reduce errors later.

Bernoulli’s Legacy in Hydraulic Engineering

Daniel Bernoulli published this principle in 1738. Although Bernoulli deduced it centuries ago, it’s still referred to as Bernoulli’s law and forms the foundation for modern fluid mechanics. Whether it’s sizing a pipe or designing a complete hydraulic power unit, engineers use this energy equation because it works.

Even with simulation software and CAD tools, the equation tells us the fundamentals, how the pressure due to fluid flow can be controlled and harnessed to get the job done.

FAQs

What does Bernoulli’s equation state?

The Bernoulli equation states that in a steady, incompressible flow of a non-viscous fluid, the sum of pressure energy, kinetic energy, and potential energy per unit weight is constant along a streamline.

Can Bernoulli’s equation be applied to hydraulic oil?

Yes. As long as the fluid flow is steady and the oil’s density remains consistent, the equation is valid. For detailed design, you may need to account for viscosity and losses.

What’s the difference between Bernoulli and the continuity equation?

The continuity equation focuses on conservation of mass, while the Bernoulli equation focuses on the conservation of energy in a moving fluid.

How does Bernoulli’s equation relate to hydraulic design?

It helps predict pressure drop, select components, and analyse how fluid velocity changes in fittings, bends, and pipe diameter transitions.

Final Word

The Bernoulli equation is a key part of any hydraulic engineer’s toolbox. It doesn’t solve every problem on its own but it lays down the groundwork. From fluid pressure changes to flow velocity analysis, from mobile rigs to process plants, this form of Bernoulli’s equation makes a difference where it counts.

Posted by admin in category Hydraulic Systems Advice on Monday, 26th January 2026