Method for determining parameters of a gas-selective electrode

Abstract

Gas-selective electrodes in liquid analyzing devices have a characteristic K with a linear portion L and a non-linear portion NL. In the non-linear portion NL, the characteristic can only be estimated so that these determinations of the concentration are rather inexact. According to the present method, the electrode is rinsed with an acid and the zero point voltage at the electrode is determined during the rinsing. Using the zero point voltage UN thus quickly obtained, the non-linear portion NL of the characteristic K can be determined with high precision so that even low concentrations c can be determined with great accuracy.

Description

The invention refers to a method for determining parameters of a characteristic of a gas-selective electrode in an automatic liquid analyzing device.

Automatic liquid analyzing devices with a gas-selective electrode are used, for example, to determine the content of ammonium in waste water. The concentration/voltage characteristic of gas-selective electrodes is always plotted logarithmically. The logarithmic characteristic of gas-selective electrodes typically is linear in the range of medium and high concentrations so that the position and the inclination of the linear portion of the characteristic can be determined by measurements using two standard solutions of different concentration. With concentrations below a limit value, the characteristic is not linear but becomes ever flatter as the concentration decreases. Determining or estimating the non-linear portion of the characteristic is effected by measurements using further standard solutions. This method is cumbersome and, moreover, inexact.

Spent gas-selective electrodes supply inexact measuring results. The degree of electrode wear can only be determined by evaluating the measuring results obtained with the standard solutions, which is inexact.

It is an object of the invention to improve the precision of measurement for measurements taken with a gas-selective electrode in an automatic liquid analyzing device.

According to the invention, this object is achieved with the features of claim 1.

According to the invention, the gas-selective electrode is rinsed with an acid. During the rinsing, the zero point voltage U_N is determined at the gas-selective electrode. The voltage value at the electrode is stored as the zero point voltage U_N as soon as the voltage has stabilized during the rinsing.

The acid removes carbonates and other contaminations from the gas-selective electrode and quickly expels measurement gas. Thus, a measurement gas concentration of almost zero at the electrode is quickly obtained so that a constant zero point voltage can be determined at the electrode after a very short period, i.e. after a few minutes at the latest.

Suitable rinsing acids are acids which, among others, contain no outgassing components. In particular, hydrochloric acid is unsuitable since it would interfere with the electrode function.

Using the method described, the zero point voltage U_N of the gas-selective electrode can be determined at any time. Therefore, the method is extraordinarily well suited to be carried out in regular intervals and automatically. This allows to draw several conclusions which, among others, allow for more exact measurement results in the range of small gas concentrations.

Preferably, the rinsing is effected during an automatic cleaning of the analyzing device. In continuous operation of the liquid analyzing device, a regular cleaning of the wet part of the analyzing device is necessary. The electrode is rinsed during the cleaning of the analyzing device so that no measuring time is wasted for rinsing and determining the zero point voltage of the gas-selective electrode.

Preferably, following the determination of the zero point voltage, a depletion signal is generated when the zero point voltage reaches or exceeds a predetermined depletion voltage value. The zero point voltage of the electrode is a reliable parameter for determining the depletion of the gas-selective electrode. In this manner, it is reliably avoided that erroneous measurements are inadvertently made with a depleted or spent electrode.

Preferably, the electrode is an ammonia electrode for determining the ammonium content in waste water. The rinsing acid may be citric acid. Generally, it may also be any other gas-selective electrode that is cleaned with an acid.

According to a preferred embodiment, the non-linear portion of the characteristic of the gas-selective electrode is determined by interpolation of the characteristic between its linear portion and the zero point defined by the zero point voltage, using an exponential function. The non-linear portion of the electrode characteristic can be represented with sufficient certainty by an exponential function. Since a relatively exact electrode characteristic can be determined in the non-linear portion, gas concentrations below a limit concentration, i.e. below the gas concentration where the characteristic passes from its linear portion to the non-linear portion, can also be determined with an exactness better than 10%.

Preferably, for c<=c_G, the interpolation is performed according to the function U=U_N(1−e^{(E/UN(log c−F))}) where

• • U is the electrode voltage,
  • U_N is the zero point voltage of the electrode,
  • E is a constant quantifying the curvature of the exponential function,
  • c is the concentration of the measuring gas,
  • c_G is the limit concentration, and
  • F is the position of the exponential function on the concentration axis.

By means of the requirements that

• • the linear and the non-linear portions of the characteristic transition at a limit point G, and
  • the transition at the limit point is always differentiable, and the function U=x log c+y for c>=c_G as well as by determining x and y by two measurements with standard solutions and by determining the zero point voltage U_N, three of the four variables U_N, E, F and c_G can be determined. Only the limit point concentration c_G or the constant of curvature E remains undetermined and has to be set.

Preferably, the constant of curvature E is set. The constant of curvature E is specific to an electrode and is determined empirically. The constant of curvature E can be determined exactly such that the error in the non-linear portion of the characteristic thus obtained is less than 100%, generally even less than 5%.

Merely by determining the zero point voltage U_N during the rinsing or cleaning interruption, the measuring range of a gas-selective electrode can be expanded to low gas concentrations in the non-linear portion of the characteristic, realizing a high determination accuracy in the non-linear portion of the characteristic. This method is generally applicable to all electrodes and is not restricted to gas-selective electrodes.

The following is a detailed description of an embodiment of the invention with reference to the drawings.

In the figures:

FIG. 1 is a schematic representation of a liquid analyzing device according to the present invention, and

FIG. 2 is a graph showing a characteristic K of a gas-selective electrode of the analyzing device.

FIG. 1 is a schematic and simplified illustration of a liquid analyzing device 10. In the present case, the liquid analyzing device 10 serves to determine the presence of ammonium in waste water. The analyzing device 10 substantially comprises a gas-selective electrode 12, a pump 22, a three-way valve 20, an acid container 18, a sodium hydroxide container 28, a sodium hydroxide pump 30, as well as a control device or processor 24 for controlling the pumps 22, 30 and the valve 20 and for evaluating the voltage signals from the electrode 12.

In measurement operation, the pump 22 pumps waste water 16 from a waste water reservoir 15 towards the electrode 12. Further, the pump 30 pumps sodium hydroxide from the container 28 into the waste water pumped towards the electrode 12. The sodium hydroxide causes an alkaline shift in the pH value of the waste water which turns the ammonium turning into ammonia. In the area of the electrode 12, the ammonia passes through a gas-selective membrane 14 so that the electrode 12 generates a voltage signal corresponding to the ammonia content of the waste water, which is evaluated by the control device 24.

The analyzing device 10 is automatically cleaned and the electrode 12 rinsed in regular intervals. To do so, the control device 24 switches the valve 20 such that acid, for example citric acid, is pumped from the acid container 18 through the pump 22 along the electrode 12. The electrode 12 is cleaned by the acid of carbonates and other contaminations and ammonia is very quickly expelled from the electrode 12. In the process, a zero point voltage U_N appears at the electrode 12, which is measured and stored by the control device 24.

Further containers with two standard solutions may be provided, with which two calibration points S₁, S₂ of the characteristic curve K shown in FIG. 2 can be determined in a linear portion L thereof.

In the diagram of FIG. 2, the electrode voltage U in millivolts (mV) is plotted versus the logarithm of the concentration log c in milligrams per litre (mg/l) and it shows the characteristic curve K of the gas-selective electrode 12. The characteristic curve K has the linear portion L for medium and high concentrations and a non-linear portion NL for low concentrations. From the two standard measuring points S₁ and S₂, the linear portion L of the electrode characteristic curve K is determined and stored in the control device 24.

Further, a predetermined constant of curvature E is stored in the control device 24.

For c<=c_G, the interpolation of the non-linear portion NL is performed according to the function U=U_N(1−e^{(E/UN(log c−F))}) where

• • U is the electrode voltage,
  • U_N is the zero point voltage of the electrode,
  • E is a constant quantifying the curvature of the exponential function,
  • c is the concentration of the measuring gas,
  • c_G is the limit concentration, and
  • F is the position of the exponential function on the concentration axis.

By means of the requirements that

• • the linear and the non-linear portions of the characteristic transition at a limit point G, and
  • the transition at the limit point is always differentiable, and the function U=x log c+y for c>=C_G and the predetermined constant of curvature E, the limit point concentration c_G can be determined and substituted in the function for the non-linear portion NL.

The constant of curvature E is specific to the electrode and is determined empirically. The constant of curvature E can be determined so exactly that the error in the non-linear portion of the characteristic thus determined is less than 10%, generally even less than 5%.

In the exemplary diagram of FIG. 2, the standard solution S₁ has an ammonium concentration of 10 mg/l and the standard solution S₂ has an ammonium concentration of 1.0 mg/l. The calibration measurements showed a voltage U_S1 of −59.3 mV for S₁ and a voltage U_S2 of 0.4 mV for S₂.

From the voltages U_S1 and U_S2, the following is obtained for the linear portion L for c>=c_G: U=log c+y with x=−59.7 mV and y=0.35 mV. 125.0 mV were measured as the zero point voltage U_N.

A value of 75.0 mV/log c was set for the curvature E.

In the present example, the control device 24 calculated a value of 0.4 mg/l for the limit concentration so that log c_G=0.4. The limit voltage U_G thus is 25.6 mV.

Thus, the non-linear portion NL is described entirely so that measurements of lower concentrations can also be performed with sufficiently high accuracy.

The depletion value for the electrode is stored as 100 mV. When the zero point voltage U_N reaches this value, a depletion signal is outputted.

Claims

1. Method for determining parameters of a characteristic of a gas-selective electrode (12) in an automatic liquid analyzing device (10), the method comprising the following steps: rinsing the electrode (12) with an acid, and determining the zero point voltage UN present at the electrode (12) during the rinsing.

2. Method of claim 1, characterized in that the rinsing is performed during an automatic cleaning of the electrode (12).

3. Method of claim 1 or 2, characterized by the output of a depletion signal when the zero point voltage UN reaches a predetermined depletion value.

4. Method of one of claims 1 to 3, characterized in that the electrode (12) is an ammonia electrode.

5. Method for determining parameters of a characteristic of a gas-selective electrode of one of claims 1 to 4, characterized in that the rinsing acid is citric acid.

6. Method of one of claims 1 to 5, characterized by the determination of the non-linear portion NL of the characteristic K of the electrode (12) by interpolation of the characteristic K between its linear portion L and the zero point voltage UN according to an exponential function.

7. Method of claim 6, characterized by an interpolation according to the function

8. Method of claim 7, characterized in that the constant of curvature E is fixed.