ASTM on Data Normalisation: Difference between revisions

ASTM D4516 - Standard Practice for Standardizing Reverse Osmosis Performance Data

Membrane performance (flux and salt passage) is affected by: water temperature, feed conductivity, and flux rate. If the operating arameters remain constant the system will perform fairly steadily over a long period of time. However, these operating conditions will eventually change. Normalisation is a technique that allows the user to standardise the data to a constant set of conditions (or to a reference), and may be used with SCADA for online diagnostics.

Flow or flux performance: specific flux, normalised flow.

${\displaystyle \operatorname {SpecificFlux} ={\frac {Flux\times TCF}{NDP}}}$

Where: ${\displaystyle \operatorname {TCF} =e^{x}}$

${\displaystyle x=u\left({\frac {1}{T+273}}-{\frac {1}{298}}\right)}$

NDP = Net Driving Pressure

${\displaystyle NDP=P_{feed}-\Delta \pi -{\frac {\Delta P}{n+1}}-P_{permeate}}$

${\displaystyle P_{feed}=}$ RO feed pressure

${\displaystyle \Delta \pi =}$ Osmotic Pressure

${\displaystyle \Delta P=}$ Feed/Brine Differential Pressure

${\displaystyle n+1=}$ Number of membrane stages

${\displaystyle P_{permeate}=}$ Permeate back pressure

${\displaystyle \pi =0.006\times }$ Average feed / brine conductivity

${\displaystyle {\text{Average feed / brine conductivity}}={\text{Conductivity of feed}}\times \left[{\frac {\ln \left({\frac {1}{1-Y}}\right)}{Y}}\right]}$

Membrane rejection: normalised salt rejection, normalised permeate Feed/brine channel blockage/fouling: normalised differential pressure.

Calculators/spreadsheets

Dow http://www.dowwaterandprocess.com/en/resources/normalization_of_membrane_systems

Hydronautics http://membranes.com/index.php?pagename=rodata