CZ20023611A3 - Equipment for chemical analysis - Google Patents

Abstract

For chemical analysis of water solution of samples there is designed an equipment comprising an electro-chemical planar sensor (2) which is an integral part of at least a bottom and/or cover (22) of the measuring cell and comprise means for adjustment of conditions of hydrodynamics within the measuring system having a distribution body (8) which is rotateably seated and engages with means for its rotation.

Description

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chemical analysis apparatus provided with an electrochemical flame sensor, measuring the whole, and means for adjusting the hydrodynamic conditions of the measuring system.

BACKGROUND OF THE INVENTION

Electrochemical analysis is a very effective analytical tool, especially since the output signal is an electrical voltage or current. The use of microelectronic technologies leads to a significant decrease in the prices of used electrodes, their miniaturization and improvement of utility properties. However, for all electrode types, response, measurement accuracy, and robustness depend significantly on the electrolyte flow with the sample to be analyzed around the electrode. One way to provide defined hydrodynamic conditions is to use an electromagtic stirrer embedded in the fluid stream to provide improved fluid distribution on the electrode working surface. A disadvantage of this arrangement is the turbulent flow around the electrode, which causes a significant increase in the noise of the output signal. Another way to achieve a defined hydrodynamic flow around the electrode is to adjust the channel profile around the electrode. The disadvantage of this solution is the possibility of depositing the compounds at the beginning or at the end of the profile. A further disadvantage is that for the use of several measuring electrodes, it is necessary to create a complex distribution profile structure, which is expensive and the resulting device is not reliable enough.

Another known method of providing defined hydrodynamics is the use of thin-layer flow by means of so-called thin-layer detectors, described for example in the work of Stulik and Pacak "Electroanalytical Measurements in Flowing Fluids" of 1989. In the first type, the cell is a U-shaped tube and the working electrode is in the center. In the second type, referred to as the "wall-jets", the whole of the tube is a T-shaped tube where the sample arm is fed with the sample, the working electrode located opposite the base arm in the transverse arm through which the sample flows. The third type is the so-called "tubular cell", with a working electrode in the tube through which the sample flows.

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All these detectors are known and work very well with one working electrode. When using multiple working electrodes, there are problems with even distribution of the liquid to the individual electrodes. When placing the electrodes one after another, another problem arises in that the electrodes lying downstream are affected by the products or reactions that take place on the preceding electrodes.

The wall-jet system has been extended to two ring-disk electrodes as described in Albery and Haggett's "New Electro-Analytical Techniques Applied to Medicine and Biology" and "Electrochemical Detectors, Fundamental Aspects and Analyticai Applications", published in 1984. It is also known to arrange objects in the vicinity of the electrode that improve hydrodynamic conditions in its vicinity. Such an embodiment has been described by Horword and Chichester in their "Instrumental Methods in Electrochemistry" published 1985. An example of this are industrial flow measurement cells with forced turbulence. In the measuring cell are placed bars, fluidized bed, packed bed, or a cylindrical electrode rotating coaxially with the whole is used. The disadvantage of these arrangements is the difficulty of extending to systems with multiple detection elements.

The best results in terms of defining hydrodynamics and mass transfer to the electrode were achieved with rotary disk electrodes. The rotating disc electrode consists of a flat disc of 1 to 3 mm diameter, located at the end of a non-conductive rod, which is immersed in solution very quickly. The solution is agitated by the rotational moment, whereby the diffusion problem is limited only by transporting the particles through a stationary layer of solution adhering to the electrode surface. If the rotation speed is constant and the stirring effect is reproducible, then the experiment is performed under the same conditions using a rotating disc electrode. A rotating disc electrode has several advantages over other rigid electrodes. These include knowledge of the hydrodynamic theory of this electrode, which allows mathematical processing of measured data with accuracy and accuracy, comparable to a mercury drop electrode. Compared to other rigid electrodes, the active electrode surface can be much more reproducibly electrochemically restored. The electrode also exhibits a higher sensitivity than conventional solid electrodes due to a defined and reproducible mixing of the solution, the diffusion problem being limited only by the stationary layer of the solution on the electrode surface. On the other hand, rotating disk electrodes also have some disadvantages, such as lower reproducibility of measurements, problematic conversion of the nA unit signal from the rotating part to the static part of the measuring device, a very difficult construction of a more complex electrode structure and correspondingly high purchase price. Other disadvantages of these devices are the complex replacement of the sensor and the fact that the test solution remains in the device, which does not allow flow analysis.

The purpose of the present invention is to overcome the drawbacks of existing solutions, to improve the hydrodynamic conditions of the system and to allow a defined alignment of the distributor to the measuring electrodes.

SUMMARY OF THE INVENTION

This purpose is achieved in a chemical analysis device with an electrochemical planar sensor measuring the whole and means for adjusting the hydrodynamic conditions of the measuring system, according to the invention, characterized in that the electrochemical flame sensor forms an integral part of at least part of the bottom and / or lid The measuring cells and the means for adjusting the hydrodynamic conditions of the measuring system are formed by a rotatably mounted guide body coupled to the means for imparting its rotation. The device can operate either in the flow mode or in the internal circulation mode of the sample. Further, according to the present invention, the bottom of the measuring cell with the sensor is removable, allowing the sensors to be replaced as needed. In a preferred embodiment, the distributor body together with the means for exerting its rotation is disposed on an arm whose position is adjustable in a direction perpendicular to the plane of the flame sensor. Also according to the invention, the distributor body is provided with a shaft with at least one longitudinally guided channel for the flow of the sample to be analyzed, which opens into the measuring cell. In a preferred embodiment, the channel is aligned coaxially with the shaft. The measured sample can be fed into the measuring cell through a flame sensor, which must be provided with a through hole for such an arrangement. In an embodiment with internal sample circulation, the shaft is preferably provided with at least one radially guided passage communicating with the channel. Better results are obtained by providing the measuring cell with an orifice arranged in the form of a disc planarly above the distributor and in the form of a ring encircling the shaft. Further improvement of the operation of the device is according to the present

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This is achieved by providing the surface of the distributor body facing the plenary sensor with protrusions and / or notches and / or roughening.

The chemical analysis apparatus of the present invention optimizes the hydrodynamic conditions of the measurement system. In addition, it allows a precisely defined alignment of the distributor over the electrodes of the flame sensor. The device can operate either in the flow mode or in the mode with internal circulation of the measured sample.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in more detail below with reference to the accompanying drawings. Fig. 1 is a partial vertical sectional view of the device; and Fig. 2 is a cross-sectional view of the measuring cell with a flame sensor as a lid in vertical section. Giant. 4 shows a vertical section measuring the whole with a flame sensor as a lid, where the drive of the distributor body is derived from a rotating disc with electromagnets and FIG. 5 shows a solution similar to that of FIG. 4 with an alternate location of the rotating disc with electromagnets. Giant. Figure 6 is an embodiment with internal sample circulation, and Figure 7 is a preferred embodiment for the embodiment of Figure 6.

Exemplary embodiment

As shown in FIG. 1, the present chemical analysis apparatus consists of a measuring cell. the sensor 2 and the rack provided with means for adjusting the hydrodynamic conditions of the measuring system.

The measuring cell 1 with the flame sensor 2 and the stand are mounted on the base 3. The stand mounted on the base 3 at a distance from the measuring cell 1 consists of a column 4 with a vertically adjustable and perpendicularly arranged arm 5 at one end. a vertical shaft 6 is mounted on the other end of which a drive electric motor 7 with a vertically arranged rotor is mounted. The shaft 6 is provided with a disc-shaped guide body 8 at its lower end. In the shaft 6 a coaxial channel 9 is formed, which is terminated on the lower surface of the distributor body 6 and is adapted at the opposite end to be connected to the sample inlet. The shaft 6 is coupled to the electric motor 7 by means of the belt 10 and the rollers 11 which are

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mounted on the shaft 6 and the pin of the electric motor 7. The guide body 8 together with the above-described means for imparting its rotation and the system for adjusting the vertical position of the arm 5 form means for adjusting the hydrodynamic conditions of the measuring system.

In the working position, the shaft 6 with the guide body 8 extends into the measuring cell 1. The height position of the guide body 8 in the measuring cell 1 is adjusted manually by sliding the arm 5 along the column 4. The arm 5 is connected to a mandrel 12 slidingly mounted in the column axis 4 and is connected to a coaxially arranged movement screw 13, which rotates in a nut 14 mounted on the column 4. Any play between the turns of the movement screw 13 is eliminated by a coil spring 15 which is mounted on the movement screw 13. The desired positioning of the distributor member 8 is assisted by an indicator 16 coupled through the movement screw 13 to the mandrel 12.

The measuring cell 1 is of cylindrical shape, with a removable bottom, sealed to the housing by means of an O-ring 17. In the bottom there is a flame sensor 2 with at least one electrode. The cell housing 1 is provided with two mounts 18 to allow assembly and securing of the measurement cell 1 by adjusting screws 19 with wing nuts 20. By tightening the wing nuts 20, the O-ring 17 is compressed and the housing common with the bottom creates a hermetic measuring cell 1. 1 is an outlet 21 in its housing.

The liquid with the sample to be measured enters the measuring cell 1 through a channel 9, which is held at its upper free end, in the space above the arm 5, by a holder 22 fixed to the arm 5. By rotating the distributor member of the body 8, the sample is evenly spread over the working electrodes of the panic sensor 2.

The described embodiment allows for a precisely defined alignment of the distributor body 8 above the electrodes and optimization of the hydrodynamic conditions of the system.

An alternative arrangement of the measuring cell 1 with the flame sensor 2 is shown in Fig. 3. The electrochemical planar sensor 2 here forms part of the cover 23 of the measuring cell 1, which is, as in the previous embodiment, sealed by an O-ring 17. torque transmission from the magnets 24 located on the pulley 11. The pulley H is again driven by a drive consisting of a driving belt IP and an electric motor (not shown) in the drawing. The liquid with the sample to be measured is fed into the measuring cell 1 by a fixed channel 9, which results in a flow channel 9, which leads to a flow channel 9, resulting in a flow channel 9. In the axis of rotation of the distributor body 8. The sample liquid outlet 21 is in the side wall of the measuring cell.

Another embodiment utilizing a thin-film type flow cell 1 is shown in Fig. 4. The liquid enters the cell 1 in the axis of rotation of the distributor body 8, which ensures its uniform distribution to the individual electrodes of the flame sensor 2 and exits radially through the outlet 21 The torque is transmitted to the distributor body 8 from the disk 25 with magnets 24, which rotates in the space above the float sensor 2 forming the lid 23 of the measuring cell L The measuring cell space 1 is sealed with an O-ring 14. The arrangement according to this embodiment is suitable for cheap applications where accuracy is not important because magnetic field lines intersect electrode connections conductively and induce interfering voltages.

This disadvantage is eliminated in the embodiment shown in FIG. 5. The function of the measuring cell 1 is similar to the previous embodiment, except that the sample liquid enters the measuring cell 1 through the opening 26 in the flame sensor. the magnet disc 24 below the flame sensor 8, so that the magnetic field lines do not close over the electrodes of the flame sensor 3, thereby reducing the induced interference voltages. The solution can be used also for analyzes running in non-flow mode, for analyzes of fixed quantity, so called „batch“ analyzes. For this mode, the shaft 6 is provided with at least one radially guided passage 27 communicating with channel Z. This results in internal circulation of the sample, whereby the liquid with the analyzed sample is returned from the outlet region 21 to passage 27 into channel 9 and thence In order to eliminate the rotation of the sample around its entrance to the distribution member 8, it is suitable, as shown in FIG. the guide member 8 is an orifice 28 which is stationary during rotation of the guide member 8. The diaphragm 28 is in the form of a disc arranged planarly above the distributor body 8 and a ring surrounding the free lower part of the shaft 6 to the mouth of the passages 27 into the channel 9.

In order to increase the efficiency of the device, especially in the case of working with viscous liquids, the front surface of the distributor member 8 may be provided with notches, protrusions, or it may be suitably roughened.

Claims (10)

PATENT CLAIMS A chemical analysis apparatus provided with an electrochemical flame sensor, measuring the whole and means for adjusting the hydrodynamic conditions of the measuring system, characterized in that the electrochemical flame sensor (2) forms an integral part of at least part of the bottom and / or lid (22) of the measuring cell (1). ), wherein the means for adjusting the hydrodynamic conditions of the measuring system are constituted by a rotatably mounted guide body (8) coupled with means for imparting its rotation. Device according to claim 1, characterized in that the bottom of the measuring cell (1) is removable. Device according to claim 1 or 2, characterized in that the measuring cell (1) is provided with an outlet (21) for draining the sample to be analyzed. Device according to one of the preceding claims, characterized in that the distributor body (8) and the means for exerting its rotation are arranged together on an arm (x) which is adjustable in a direction perpendicular to the plane of the flame sensor. Apparatus according to claim 1 or 2, characterized in that the distributor body (8) is provided with a shaft (6) with at least one longitudinally extending channel (9) for the flow of the analyzed sample to the measuring cell (1). Device according to claim 5, characterized in that the channel (9) is guided coaxially with the shaft (6). Device according to claim 5 or 6, characterized in that the shaft (6) is provided with at least one radially guided passage (26) communicating with the channel (9). « • with * · « with in « se • with and »» • · « and * 0 • • with • • ♦ ·· • se • e · se · stas Device according to any one of claims 1 to 4, characterized in that the flame sensor (2) is provided with at least one opening (25) for entering the analyzed sample into the measuring cell (1). Device according to any one of the preceding claims, characterized in that the surface of the distributor body (8) facing the plane sensor (2) is provided with protrusions and / or notches and / or roughening. Apparatus according to claim 7, characterized in that the measuring cell (1) is provided with an orifice (27) arranged in the form of a disc planar parallel to the distributor body (8) and in the form of a ring around the shaft (6).