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Useful information on pipe velocity

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19/05/2022, 12:45
Useful information on pipe velocity
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Useful information on pipe velocity
The careful design and selection of pipework in a system reduces frictional
At low velocities, fluids flow in a regular manner with a constant velocity and
with no vertical mixing across the wave front. This is termed laminar flow. At
high fluid velocities, eddies (flow currents) are formed which lead to random
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losses and improves the performance of pumps and other equipment.
mixing throughout the flow cross-section. This is called turbulent flow. At
intermediate flow rates, there is always a laminar flow region close to the pipe
walls and this can vary in thickness depending on the roughness of the pipe
material and the overall flow velocity. The point at which the flow ceases to be
laminar and becomes turbulent is called the critical velocity.
Pumps, and especially centrifugal pumps, work most efficiently when the fluid
is delivered in a surge-free, smooth, laminar flow. Any form of turbulence
reduces efficiency, increases head loss and exacerbates wear on the pump’s
bearings, seals and other components.
How is Pipe Velocity calculated?
Pipe velocity is an area averaged property which is independent of the pipe’s
cross-sectional flow distribution and whether the flow is laminar or turbulent.
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Useful information on pipe velocity
For example, along the central axis, fluid may be travelling at twice the
calculated pipe velocity.
What is head loss?
Within a pipe, frictional contact with the walls means that fluid flow is highest
causes a pressure and energy loss along the pipe and this is much greater
with turbulent flow. Whereas with a laminar flow, pressure loss is proportional
to pipe velocity, in turbulent flow it is proportional to its square.
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on the pipe axis and effectively zero at the pipe wall. The frictional contact
What is the Reynolds Number?
The transition from laminar to turbulent flow can be assessed from a
calculation of the Reynolds number. This is a dimensionless number
determined from the pipe diameter, the density and viscosity of the flowing
fluid and the flow velocity:
The Reynolds Number is effectively the ratio of the forces of mass flow and
shear stress due to the fluid’s viscosity. Pipe flow can be considered to be
laminar if the Reynolds number is less than 2000 and fully turbulent if it is
greater than 4000. Flow characteristics are unpredictable if the value is
between these two values.
What is a ‘good’ pipe velocity?
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19/05/2022, 12:45
Useful information on pipe velocity
An installation engineer chooses pumps and sizes pipework to achieve a
satisfactory pipe velocity. For water-like liquids with no entrained solids (for
example: chemicals, paints, petrol, beverages), a pipe velocity of about 1 – 2
m/s is considered an acceptable value. If a system contains any narrow pipes
or other constrictions, the pipe velocity will be a lot higher at these points.
If the liquid is shear-sensitive or can foam or change properties, a lower pipe
velocity may be targeted with larger diameter pipework. On the other hand, if
the fluid contains solids that could settle and form blockages at low flow rates,
a higher pipe velocity (5-6 m/s) may be required.
The following table lists some typical pipe velocities for a range of common
industrial feeds:
Typical Pipe Velocity (m/s)
Water
0.9 - 2.4
Carbon tetrachloride
1.8
Chlorine, liquid
1.5
Ethylene glycol
1.8
Hydrochloric acid
1.5
Oil lubricating
1.5
Sulfuric acid
1.2
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Fluid
Summary
Pumps, and especially centrifugal pumps, work most efficiently when the fluid
is delivered in a surge-free, smooth, laminar flow. Any form of turbulence
reduces efficiency, increases head loss and exacerbates wear on the pump’s
bearings, seals and other components.
Pipe size and hence pipe velocity can have a significant effect on system
performance on both the suction and discharge side of a pump. For water-like
liquids with no entrained solids (for example: chemicals, petrol, beverages), a
pipe velocity of about 1 – 2 m/s is considered suitable. However, with feeds
containing entrained solids, pipe flow may need to be increased to eliminate
the risks of sediment deposition. Fittings such as elbows and reducers should
be selected to avoid restrictions that could encourage blockages. Conversely,
with
containing
dissolved gases, or sensitive to shear, turbulence
may
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Useful information on pipe velocity
cause the liquids to degas and foam such that a lower flow and/or larger pipe
size may be advisable.
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