SE457190B - CIRCUIT DEVICE FOR COULOMETRIC TITRATION - Google Patents

Description

457 190 10 15 20 25 30 35 2 setting is suggested instead of setting the current via voltage.

The known titration apparatuses, which regulate the generator current in dependence on the indicator signal, in principle switch off the generator current when a certain threshold value is reached or even allow negative generator currents through their circuit structure. For this reason, with these devices no permanently effective regulation of the generator current can be carried out around the titration end point.

Especially when carrying out a number of titrations on the same basic solution, ie without changing the basic solution, disturbances in the titration breaks cause reactions, which consume measuring solution in the measuring vessel. The consumption of measurement solution is reflected in the fact that the indicator signal slowly decreases. If a new titration is then performed in the same basic solution, an amount of current must first be produced, which cancels out this disturbance reaction. Only then can the probe make a contribution to the titration.

The first-mentioned current fraction is strongly prominent as a measurement error, and this in particular depends on the length of the titration pause. An example of these disturbance reactions is the reaction of selenium in hypobromite titration of ammonia. In DD- “Ps 122 258, 133 765 and DE-As 2 921 651. post-titration is suggested as a way out. The post-titration serves the purpose of avoiding serious errors and long-term operation. However, the source of error based on the disturbance reaction is not completely eliminated, since the measurement result depends on the time of the start of the new titration in the interval between two post-titrations. As a result, the accuracy of the measurement results is significantly reduced.

The object of the invention is to reduce the measurement error in the case of multiple titrations with the same basic solution.

The object of the invention is to provide a circuit device for coulometric titration with a compensation of the disturbing action of oxidizing ions. Including the said functional steps, the invention provides the following solution to this problem: The difference amplifier for the indicator signal and the power amplifier in the generator circuit are connected in an amplifier. The working electrode is directly connected to the output of the differential amplifier. The auxiliary electrode is directly connected to earth potential via the measuring resistor and the negative amplifier's negative operating voltage input.

A start-stop discriminator is arranged for the measurement value formation. It is connected on the input side to a circuit point, which leads to a voltage proportional to the indicator signal, and to a setpoint sensor for the titration end point.

An embodiment of the invention will be described in more detail in the following with reference to the accompanying drawings. Fig. 1 is a schematic diagram of a circuit arrangement according to the invention. Fig. 2 shows titration processes with and without compensation according to the invention of the effect of interference ions.

A measuring vessel or a measuring cell 1 is by means of a partition wall with a membrane 4 divided into two chambers 2, 3, which are filled with an electrolytic basic solution 6. In the chamber 3, polarizable indicator electrodes 7, 8 and the working electrode 9 in the titration electrode pair are arranged. .

The associated auxiliary electrode 10 is immersed in the chamber 2.

The indicator electrodes 7, 8 are connected to the input of an indicator circuit 11. The titration electrodes 9, 10 are connected to the output of a generator circuit 12. Between the indicator circuit 11 and the generator circuit 12, an optocoupler 13 is connected as a galvanic isolating stage. The output of the generator circuit 12 is also connected to the input of a measured value generator 14.

An operating voltage Ua is applied to the indicator electrode 7 via a resistor 15. The indicator electrode 7 is directly connected to the input of a first amplifier 16, the output of which is connected to a switch 18 and to an inverting amplifier 17. The amplifier 17 has 457 190 10 15 20 25 30 The gain factor 1. It enables the measurement of reverse titration processes. The output of the amplifier 17 is connected to a second selector contact in the switch 18, the third contact of which is connected to the input of the optocoupler 13. The amplifiers 16, 17 and the switch 18 form the indicator circuit 11.

The output of the optocoupler 13 is connected to the input of a differential amplifier 19 and to the input of a start-stop discriminator 22. The reference input of the differential amplifier 19 is connected to a setpoint sensor in the form of a voltage divider consisting of two resistors 20, 21. The output of the differential amplifier 19 is directly connected to the working electrode 9, while the auxiliary electrode 10 is connected to earth via the measuring resistor 32. The auxiliary electrode 10 is also connected to the measured value input of the measured value generator 14. On the supply side, the differential amplifier 19 is connected to an input of a positive operating voltage Ua and with its input 34 of the negative operating voltage connected to earth. The earth potential forms a voltage reference point 33 for the auxiliary electrode 10. The amplifier 19, the setpoint sensor and the titration electrodes 9, 10 form the generator circuit 12. The start-stop discriminator 22 consists of a comparator 23, a rocker 24 connected thereto with a delay element 25 in the reset circuit. management and a setpoint sensor for the titration endpoint. The setpoint sensor is constructed in the form of a voltage divider of resistors 26, 27. It is connected to an operating voltage Ua, like the setpoint sensor of the differential amplifier 19. The output of the flip-flop 24 is connected to the control input of the measured value generator 14.

The core of the measured value generator 14 is an analog-to-digital converter 28, which on the output side is connected to an indicator 29. It further has inputs for connecting an empty value selector 30.

In the chamber 3 a stirrer 31 is arranged.

The described circuit device has the following mode of operation: The titration is started with supply to the chamber 3 of the sample 5 to be determined. The measuring solution present in the basic solution reacts immediately with the sample 5, whereby the indicator current Ji and thus the indicator signal drops practically to zero. The decrease of the indicator signal manifests itself at the input of the differential amplifier 19 in an increase of the differential voltage, which produces a generator current Jg. This produces a new electrochemical measurement solution, which immediately reacts with the sample. The diaphragm 4 prevents the measuring solution from being exceeded into the chamber 2. As the equivalence point approaches, the concentration of the measuring solution acting at the indicator electrodes 7, 8 rises again. This again results in an indicator signal, which reduces the differential voltage and thus the generator current J. At the equivalence point, the differential voltage and the generator current Jg are zero, ie the titration is completed. This condition would be permanent if interference ions did not react with the measurement solution. However, the loss of measuring solution is compensated in the circuit device by means of a control process. The decrease of the indicator current Ji leads to a differential voltage at the input of the differential amplifier 19 and consequently to a generator current Jg. This generates a new measurement solution, so that the indicator current Je increases again. The indicator current Ji and the generator current Jg only fluctuate slightly around a constant value. Thus, regardless of the time of a new titration, the indicator current Ji and the generator current Jg are practically constant and the same measurement conditions exist all the time. A generator current Ji in the other direction as a result of exceeding the threshold voltage given by the setpoint sensor 20, 21 is not possible, since the voltage reference point 33 and the input 34 are grounded, ie have the same potential. This would disturb the equilibrium of the measuring vessel 1.

The output voltage of the optocoupler 13 is compared in the comparator 23 with the voltage above the resistor 26 at the equivalence point of the setpoint sensor. Similarly, the output of the comparator 23 switches the flip-flop 23 via the delay element 25 to the second stable state, which in turn interrupts the analog-to-digital conversion and the integration in the analog-to-digital converter 28 by means of a stop signal. renewed titration, the output voltage of the optocoupler 13 becomes again greater than the voltage across the resistor 26. The comparator 23 now transmits the flip-flop 24 in the second state, which the flip-flop acknowledges with a start signal to the analog-to-digital converter 28. Even during the titration, interference reacts with the measurement solution. The resulting idle value is input to the analog-to-digital converter 28 by means of the idle value selector 30 and subtracted there automatically. The results of the coulometric measurement on the sample are shown numerically on the indicator 29. Fig. 2 shows titration curves in the form of time diagrams for the indicator current Ji and the generator current Jg in the following three cases: a) Titration without compensation of disturbance b) Titration with post-titration C) the invention.

The dashed surfaces represent the amounts of electricity consumed in each case and thus the amounts of material analyzed.

Claims (3)

10 15 20 25 457 190 PATENT REQUIREMENTS 1. A circuit device for coulometric titration having a measuring cell (1), an indicator circuit (11), a step (13) for galvanic isolation, a generator circuit (12) and a measured value generator (14), therefrom, a difference amplifier and a power amplifier are connected in an amplifier (19), that a working electrode (9) is directly connected to the output of the differential amplifier (19), that an auxiliary electrode (10) via a measuring resistor (32) and an input (34) for negative operating voltage to the differential amplifier (19) is at ground potential and that a start-stop discriminator (22) is arranged for the measurement value formation and on the input side is connected to a circuit point, which leads a voltage proportional to the indicator signal, and a setpoint sensor (26, 27 ) for the titration endpoint. 2. A circuit arrangement according to claim 1, characterized in that the differential amplifier (19) is connected to an indicator signal amplifier (16, 17) via an optocoupler (13). Circuit arrangement according to Claims 1 and 2, characterized in that the start-step discriminator (22) consists of a comparator (23) and a flip-flop (24) with delay elements (25) in the reset line, the comparator (23 one input is connected to the output of the optocoupler (13) and the output of the flip-flop (24) is connected to the control input of an analog-to-digital converter (28).