2 operational theory model ot-2 system – Teledyne OT-2 - Oxygen transmitter system User Manual
Page 12
Teledyne Analytical Instruments
2-4
2 Operational Theory
Model OT-2 System
Warning:The sensor used in the Model OT-2 System uses electro-
lytes which contain substances that are harmful if
touched, swallowed, or inhaled. Avoid contact with
ANY fluid or powder in or around the unit. What may
appear to be plain water could contain one of these
harmful substances. In case of eye contact, immedi-
ately flush eyes with water for at least 15 minutes. Call
physician. (See Appendix - Material Safety Data Sheet
(MSDS)).
2.2.3 Electrochemical Reactions
The sample gas diffuses through the Teflon membrane. For a
sensor that employs KOH as electrolyte, oxygen in the sample gas
is reduced on the surface of the cathode according to the follow-
ing HALF REACTION:
O
2
+ 2H
2
O + 4e
–
® 4OH
–
(cathode)
(Four electrons combine with one oxygen molecule—in the
presence of water from the electrolyte—to produce four hydroxyl
ions.)
When the oxygen is reduced at the cathode, lead is simulta-
neously oxidized at the anode by the following HALF REACTION:
Pb + 2OH
–
® Pb
+2
+ H
2
O + 2e
–
(anode)
(Two electrons are transferred for each atom of lead that is
oxidized. Therefore it takes two of the above anode reactions to
balance one cathode reaction and transfer four electrons.)
The electrons released at the surface of the anode flow to the
cathode surface when an external electrical path is provided. The
current is proportional to the amount of oxygen reaching the
cathode. It is measured and used to determine the oxygen con-
centration in the gas mixture.
The overall reaction for the fuel cell is the SUM of the half
reactions above, or:
2Pb + O
2
® 2PbO
(These reactions will be the dominant sensor current compo-
nent as long as no gaseous components capable of oxidizing
lead—such as iodine, bromine, chlorine and fluorine—are present
in the sample.)
In the absence of oxygen, the output of the sensor is approxi-
mately zero.