| 1 |
The
sensor does not use replaceable membranes or cartridges. This
will significantly reduce the maintenance time required to
keep the system operational. |
| 2 |
There
are no consumables (membranes, electrolyte, and anode) so
the cost of ownership is reduced. |
| 3 |
The
sensor does not require routine calibration, due to the fact
that there is no anode that is oxidizing, decreasing maintenance
time and increasing reliability. |
| 4 |
Fouling
of the sensor does not have an effect on accuracy so routine
sensor cleaning is not required. This decreases maintenance
and increases reliability. |
| 5 |
There
is no need for sensor preparation or initial calibration at
start-up, reducing the amount of time required to get the
system operational. |
| 6 |
Increased
reliability of the system allows for better control of aeration
saving the customer up to 30% in the cost of aeration. |
| 7 |
There
is no minimum flow requirement allowing the sensor to be mounted
in almost any location, especially helpful in fine bubble
diffuser basins were there is minimum agitation. |
| 8 |
The
system has two isolated 4-20 (0-20) outputs, four relays,
and a Modbus RTU output allowing the customer to interface
with the analyzer in whatever way they desire. |
| 9 |
The
LCD display is backlit, and uses the high temperature and
UV resistant glass and fill. There is a contrast adjust on
the front panel. This will ensure that the display is always
easily readable. |
| 10 |
Initial
setup of the analyzer is accomplished through plain English
menus on the display allowing for quick, easy setup. |
| 11 |
System
accuracy is .05 PPM allowing for accurate monitoring of anoxic
and anaerobic zones. |
