ASTM on Data Normalisation: Difference between revisions

Latest revision as of 16:11, 2 December 2024

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

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

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

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

NDP = Net Driving Pressure

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

$P_{feed}=$ RO feed pressure

$\Delta \pi =$ Osmotic Pressure

$\Delta P=$ Feed/Brine Differential Pressure

$n+1=$ Number of membrane stages

$P_{permeate}=$ Permeate back pressure

$\pi =0.006\times$ Average feed / brine conductivity

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

$Y={\text{Recovery}}={\frac {\text{Permeate flow}}{{\text{Concentrate flow}}+{\text{Permeate flow}}}}$

Normalised Flow

${\text{Normalised Permeate Flow}}={\frac {\left(NDPs\right)\left(TCFs\right)}{\left(NDPa\right)\left(TCFa\right)}}{\text{Actual Flow}}$

$a={\text{actual}}$
$s={\text{standard}}$

==Membrane rejection

Normalised Salt Rejection

Normalised Permeate Conductivity

${\text{Normalised permeate conductivity}}={\text{Permeate conductivity}}\left({\frac {\text{Actual permeate flow}}{\text{Standard permeate flow}}}\right)\left({\frac {\text{Standard feed/brine conductivity}}{\text{Actual feed/brine conductivity}}}\right)\left(TCF\right)$

Feed/brine channel blockage/fouling

Normalised differential pressure

${\text{Normalised}}\ \Delta P=\Delta P\left[{\frac {\left({\text{Standard feed/brine flow}}\right)^{1.5}}{\left({\text{Actual feed/brine flow}}\right)^{1.5}}}\right]\left[\left(T-25\right)\left(0.017\right)+1\right]$

${\text{Feed/brine flow}}={\frac {\left({\text{Feed flow}}+{\text{Concentrate flow}}\right)}{2}}$

Calculators/spreadsheets

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

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

@@ Line 67: / Line 67: @@
 ===Normalised Flow===
+<math>
+\text {Normalised Permeate Flow} = \frac{\left ( NDPs \right ) \left ( TCFs \right )}{\left ( NDPa \right ) \left ( TCFa \right )} \text {Actual Flow}
+</math>
+<p>
+<math>
+a = \text {actual}
+</math>
+<br>
+<math>
+s = \text {standard}
+</math>
+</p>
-==Membrane rejection - normalised salt rejection, normalised permeate==
+==Membrane rejection
-==Feed/brine channel blockage/fouling - normalised differential pressure==
+===Normalised Salt Rejection===
+===Normalised Permeate Conductivity===
+<math>
+\text {Normalised permeate conductivity} = \text {Permeate conductivity}\left ( \frac{\text {Actual permeate flow}}{\text {Standard permeate flow}} \right )\left ( \frac{\text {Standard feed/brine conductivity}}{\text {Actual feed/brine conductivity}} \right )\left ( TCF \right )
+</math>
+==Feed/brine channel blockage/fouling==
+=== Normalised differential pressure===
+<math>
+\text {Normalised}\ \Delta P=\Delta P\left [ \frac{\left ( \text {Standard feed/brine flow} \right )^{1.5}}{\left (\text {Actual feed/brine flow}  \right )^{1.5}} \right ]\left [\left ( T-25 \right )\left ( 0.017 \right ) +1 \right ]
+</math>
+<p>
+<math>
+\text {Feed/brine flow}=\frac{\left ( \text {Feed flow} + \text {Concentrate flow} \right )}{2}
+</math>
+</p>
 ==Calculators/spreadsheets==