Darcy-Weisbach vs. Hazen-Williams: Pipe Friction Loss Compared

When pressure loss hits harder than expected, you end up with underperforming cylinders, oversized pumps and wasted energy. In hydraulic systems, whether it’s on a powerpack, a cylinder loop or a hose run, getting head loss calculations wrong means redesigns, downtime and additional cost.

Which leads us to the two most common methods for calculating head loss due to friction in fluid.
The Darcy-Weisbach equation and the Hazen-Williams formula.

So which one’s right for your next system design?

Understanding the Darcy-Weisbach Equation for Accurate Head Loss Calculation

The Darcy-Weisbach equation is the go-to for engineers working with pipe flow in hydraulic systems. It’s one of the few equations that reliably handles pressure loss across a range of fluids, temperatures and flow regimes.

Darcy-Weisbach Formula for Head Loss in Pipe Flow:

hL = f * (L/D) * (V² / 2g)

Where:

• hL = head loss
• f = Darcy friction factor
• L = pipe length
• D = pipe diameter
• V = flow velocity
• g = gravity

This equation is based on fluid mechanics fundamentals. It’s valid for fully developed single-phase flow, whether it’s laminar or turbulent.

In short, the Darcy-Weisbach equation can be used across:

• High-pressure systems
• Variable temperatures
• Hydraulic oils with mixed viscosity
• Stainless or steel pipe with varying relative roughness

Simplified Friction Loss Estimation with the Hazen-Williams Formula

The Hazen-Williams equation is easier to work with but it’s a shortcut. It skips viscosity, density, and flow regime, replacing those with an empirical coefficient.

Hazen-Williams Formula for Water Flow Loss in a Pipeline:

hL = (4.727 * L * Q^1.852) / (C^1.852 * D^4.87)

You’ll find it used in civil engineering and plumbing, where:

• Fluids are usually cold water
• Flow is always turbulent
• Pressure loss is low-stakes
• Accuracy isn’t critical

It’s not built for oil. And it can’t handle what the Darcy-Weisbach friction factor gives you in terms of flexibility or accuracy. It assumes the pipe stays in perfect condition and ignores turbulence changes.

For the most part this makes it unsuitable for hydraulic system design.

Comparing Darcy-Weisbach and Hazen-Williams in Head Loss Calculations

Feature	Darcy-Weisbach	Hazen-Williams
Fluid	Any Newtonian fluid	Water only
Accuracy	High	Low
Flow regime	Laminar & turbulent	Turbulent only
Friction factor	Calculated	Preset coefficient
Handles viscosity	Yes	No
Used in	Hydraulics, oil flow, powerpacks	Plumbing, irrigation

Only Darcy-Weisbach offers a reliable method for calculating head loss due to friction in fluid flow, especially where pressure drop matters.

Friction Factor Calculation: The Key to Accurate Pressure Loss

The most critical part of using Darcy-Weisbach correctly is calculating the friction factor f.

That’s where tools like the Moody diagram, Colebrook equation or a pressure loss calculator come in.

Moody Friction Factor - Visual Method:

Use a chart or equation to match:

• Reynolds number (Re)
• Relative roughness (ε/D)

Colebrook Equation - Iterative Method:

1/√f = -2 log10( (ε/D)/3.7 + 2.51/(Re√f) )

This method is widely used in hydraulic design software to deliver accurate friction factor calculation for turbulent flow.

Heads up: For steel pipes, relative roughness affects the outcome more than you'd think. As pipes wear, flow resistance goes up - so you need a method that reacts to that.

How to Calculate the Pressure Loss in Hydraulic Systems Using Darcy-Weisbach

Let’s take an example using ISO 46 hydraulic oil in a pipe flow between a tank and a valve:

Step-by-step calculation:

1. Work out the flow velocity (V): V = Q / A
2. Get Reynolds number (Re) using: Re = (ρVD)/μ
   This gives you the flow regime - laminar or turbulent.
3. Determine relative roughness: ε / D
4. Use Colebrook or Moody to find f - or shortcut with a reliable friction loss calculator.
5. Calculate head loss: Plug into Darcy-Weisbach and find hL
6. Convert head loss to pressure drop: ΔP = ρg * hL

This is the accurate method for calculating head and pressure loss in fluid flow systems. Every variable - viscosity, density, roughness - gets taken into account.

Why Hazen-Williams Doesn’t Work for Hydraulic Powerpacks or Pipe Flow

In powerpacks, flow direction changes, temperature increases and flow rates vary through the cycle. Hazen-Williams and Darcy-Weisbach equations aren’t interchangeable here - Hazen-Williams just doesn’t hold up.

Why?

• It assumes fully turbulent flow
• It uses a fixed C coefficient, ignoring oil viscosity
• It’s based on empirical data from water-only systems

That’s fine in fire suppression or irrigation but not where you’re working with 210-bar pressure circuits and dynamic oil flow.

Dimensionless Friction Factors and Flow Resistance Equations

The Darcy friction factor is dimensionless, which is why it works across different units and systems. You’ll also see terms like:

• Fanning friction factor - ¼ of Darcy
• Moody friction factor - another name for the same variable depending on the diagram used

These help engineers understand how much flow resistance is present in a system, especially at higher flow velocities where turbulence dominates.

Hydraulic components - from valves to heat exchangers - all feel the impact of frictional head loss. A good design accounts for this loss in a pipeline and keeps pressure drop across components within spec.

When to Use Each Equation: Hazen-Williams vs Darcy-Weisbach

Use Darcy-Weisbach when:

• The fluid isn’t water (i.e. oil, glycol, blends)
• You're handling pressure loss calculation
• You're sizing a hydraulic power unit
• You need accurate pressure loss data to avoid oversizing

Only use Hazen-Williams when:

• It’s cold water
• The stakes are low
• It’s part of a water system spec, not hydraulic design

FAQs: Darcy-Weisbach and Pressure Loss in Hydraulic Systems

What’s the most accurate way to calculate head loss due to friction in hydraulic systems?

Use the Darcy-Weisbach equation. It gives the most precise results and works for a wide range of fluid mechanics applications.

Is the friction factor dimensionless?

Yes - the Darcy friction factor is a dimensionless coefficient, determined by pipe roughness and flow regime.

Can I calculate pressure loss using just Hazen-Williams?

Not accurately - Hazen-Williams is based on empirical data and doesn’t handle viscosity, Reynolds number, or fluid types beyond water.

What’s the best method for calculating the friction factor for turbulent flow?

Use the Colebrook equation or a Moody chart for detailed accuracy, or plug values into a pressure loss calculator for speed.

What’s the difference between Darcy friction factor and Fanning friction factor?

The Fanning friction factor is exactly one-fourth of the Darcy friction factor. Just be clear which one you’re using - they give different results unless converted.

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