Xi. addendum – Myron L 729II User Manual

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XI. ADDENDUM

A. pH, ORP and TEMPERATURE RELATIONSHIPS

1. pH

a. pH as an Indicator

pH is the measurement of Acidity or Alkalinity of an aqueous

solution. It is also stated as the Hydrogen Ion activity of a

solution. pH measures the effective, not the total, acidity of a

solution.

A 4% solution of acetic acid (pH 4, vinegar) can be quite

palatable, but a 4% solution of sulfuric acid (pH 0) is a violent

poison. pH provides the needed quantitative information by

expressing the degree of activity of an acid or base.

In a solution of one known component, pH will indicate

concentration indirectly. However, very dilute solutions may be

very slow reading, just because the very few ions take time to

accumulate.

b. pH Units

The acidity or alkalinity of a solution is a measurement of the

relative availabilities of hydrogen (H ) and hydroxide (OH-) ions.

An increase in (H+) ions will increase acidity, while an increase in

(OH-) ions will increase alkalinity. The total concentration of ions

is fixed as a characteristic of water, and balance would be 10-7

mol/liter (H+) and (OH-) ions in a neutral solution (where pH

sensors give 0 voltage).

pH is defined as the negative logarithm of hydrogen ion

concentration. Where (H+) concentration falls below 10-7,

solutions are less acidic than neutral, and therefore are alkaline.

A concentration of 10-9mol/liter of (H+) would have 100 times less

(H+) ions than (OH-) ions and be called an alkaline solution of pH

9.

c. The pH Sensor

The active part of the pH sensor is a thin glass surface which is

selectively receptive to hydrogen ions. Available hydrogen ions in

a solution will accumulate on this surface and a charge will build

up across the glass interface. The voltage can be measured with

a very high impedance voltmeter circuit; the trick is to connect

the voltmeter to solution on each side.

The glass surface encloses a captured solution of potassium

chloride, holding an electrode of silver coated with silver chloride.

This is as inert a connection as can be made from metal to an

electrolyte. It still can produce an offset voltage, but using the

same materials to connect to the solution on the other side of the

membrane allows the 2 equal offsets to cancel.

The problem is the other side of the membrane is some test

solution, not potassium chloride. The outside electrode, also

called the Reference Junction, is of the same construction with a

porous plug in place of a glass barrier to allow the junction fluid to

contact the test solution without significant migration of liquids

through the plug material. Migration does occur, and this limits the

lifetime of a pH junction, from depletion of solution inside the

reference junction or from contamination.

d. The Myron L pH Sensor

The pH sensors for the 720 Series II Monitor/controller are a

single construction in an easily replaceable package. The sensor

body holds large solution supply for long life. The reference

junction “wick” is porous to provide a very stable, low permeability

interface. It is located under the glass pH sensing electrode. The

construction combines all the best features of any pH sensor

known.

e. Sources of Error

1. Reference Junction

The most common sensor problem is usually a clogged junction.

The symptom is a drift in the “zero” setting at 7 pH. This is why the

Monitor/controller does not allow more than 1 pH unit of offset

during calibration. At that point the junction is unreliable.

2. Sensitivity Problems

Sensitivity is the receptiveness of the glass surface, which can

be diminished by a film on the surface, or a crack in the glass.

These problems also cause long response time.

3. Temperature Compensation

pH sensor glass changes its sensitivity slightly with temperature,

so the further from pH 7 one is, the more effect will be seen. A pH

of 11 at 40°C would be off by 0.2 units. The sensor senses the

solution temperature, sends the data to the Monitor/controller

which compensates the reading.

2. ORP/Oxidation-Reduction Potential/REDOX

a. ORP as an Indicator

ORP is the measurement of the ratio of oxidizing activity to

reducing activity in a solution. It is the potential of a solution to

give up electrons (oxidize other things) or gain electrons (reduce).

Like acidity and alkalinity, the increase of one is at the expense of

the other, so a single voltage is called the Oxidation-Reduction

Potential, with a positive voltage showing, a solution wants to

steal electrons (oxidizing agent). Chlorinated water will show a

positive ORP value, for instance.

b. ORP Units

ORP is measured in millivolts, with no correction for solution

temperature. Like pH, it is not a measurement of concentration

directly, but of activity level. In a solution of only one active

component, ORP does indicate concentration. Also, as with pH, a

very dilute solution will take time to accumulate a readable

charge.

c. The ORP Sensor

An ORP sensor uses a small platinum surface to accumulate

charge without reacting chemically. That charge is measured

relative to the solution, so the solution “ground” voltage comes

from a reference junction - same as the pH sensor uses.

d. The Myron L ORP Sensor

The ORP sensors for the 720 Series II Monitor/controller are a

single construction in an easily replaceable package. The sensor

body holds large solution supply for long life. The reference

junction “wick” is porous to provide a very stable, low permeability

interface. It is located under the platinum sensing electrode. The

construction combines all the best features of any ORP sensor

known.

Both pH and ORP will indicate 0 for a neutral solution. Calibration

at zero compensates for error in the reference junction.

A zero calibration solution for ORP is not practical, so the

Monitor/controller uses the offset value determined during

calibration to 7 in pH calibration (pH 7 = 0 mV). Sensitivity of the

ORP surface is fixed, so there is no gain adjustment either.