

INTELLIGENT CHEMICAL DOSING
Exceeding Industry Standards in scale prediction for even the most
stressed applications with Complex Ion (Ci) Intelligence.
Accurate
Precise dosing projections for the most complex waters and high recovery applications
Reliable
All calculations are based on published research and scientifically proven, industry accepted calculations
Innovative
Considers critical variables: saturation constants (Ksp), temperature correction factors, individual ion product calculations and rate of reaction
NEW Advisor™Ci 4.5.0 Now features a brine concentrator function
The AdvisorCi brine concentrator acts as an additional stage and can model any type of system post RO used to increase recovery. This allows for simultaneous variations of the main RO and brine concentrator RO’s recovery rates, to allow the designer to maximize the overall recovery. The brine concentrator feature allows for an antiscalant that is different from the primary RO antiscalant to be dosed in the concentrator system. The feature also permits the user to enter an inter-stage pH adjustment if needed to further increase recovery. This design has been found to be highly accurate for designing newer technology processes such as closed circuit desalination systems.


THE MOST ACCURATE CHEMICAL DOSING
SOFTWARE TO PREDICT SCALE FORMING
COMPOUNDS IN REVERSE OSMOSIS SYSTEMS.
NEW brine concentrator function
Simultaneously design an RO and a second RO operating on the concentrate of this plant.
Robust Calculation Engine
A proprietary combination of advanced calculations and scientifically validated CCPP accurately predicts the activity of all scale forming compounds for membrane applications
Metal Dosing Factor
Analyzes and adjusts for potential precipitation of metals based on their state of oxidation
Rate of Reaction
Adjusts antiscalant does according to the feed stream analysis and determines rate of precipitation
High Recovery Applications
Applies precise calculations derived from on-site research of waters with high ionic strength to reduce the saturation potential of sparingly soluble salts
