NL8403355A - OXYGEN CELL. - Google Patents

Description

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843l24 / vdKl / vL

Short designation: Oxygen cell

Applicants are named as inventors

Michele Petrucci and Virgilio Cresti

In an oxygen cell where the unknown partial pressure of oxygen is determined by measuring the emk of a concentration cell, oxygen with a known partial pressure is formed by a substance which reacts with oxygen to form compounds which are depleted of the reaction medium deleted.

Thus, for example, the polarization problem of the cell is avoided, its useful life is considerably extended and the signal remains extremely accurate over long periods of time.

The invention relates to the improvement of dust cells and, in particular, to solving the problem of long-term reliability of measurements for determining the oxygen content in liquid media at high temperature.

The determination of oxygen in liquid media at high temperature is increasingly used in the control and regulation of many industrial processes, such as the preparation of metals and alloys in the molten state, the annealing and the carburation of metals, the sintering of ores , combustion etc. The oxygen cell is usually used for this purpose. The cell consists of a chamber whose walls are made of suitably stabilized zirconia that becomes permeable to oxygen ions above a certain temperature, typically around 500 ° C.

By forming a known partial oxygen pressure in the chamber, a concentration cell is obtained whose electromotive force (emk) is expressed by Nernst's equation 30: 8403355

J

-2-? - - '\

P

E = fln- ^

° 2X

where E is the emk of the cell, P_ is the known partial oxygen

U2R

pressure and ΡΛ is the partial pressure that you wish to measure.

U2X

The problem is getting a ΡΛ that lasts for

Ü2R

5 remains known for a long time, enabling precise control at any time.

There are two ways to obtain the known partial oxygen pressure; the first way is that a continuous flow of gas of known composition is introduced into the chamber. This means that the walls of the measuring cell and the gas supply pipe must be completely leak-proof or that in any case they do not allow any impurities in the chamber that could change the composition of the reference gas.

Due to the thermal and mechanical shocks to which these cells are usually subjected, this condition is rather difficult to maintain, so that the cost is high, while there are still doubts as to the long-term effective reliability of the measurements. Furthermore, technical and economic requirements currently mean that the gas supply lines cannot exceed a certain length, which is typically around 70-100 cm, thus considerably limiting the scope of such an apparatus.

The second way is to introduce complex metal oxide mixtures into the chamber, which at equilibrium ensure the known partial oxygen pressures at different temperatures.

The drawback of these devices is that they only work properly for a limited period of time, because the oxygen passing through the walls of the chamber reacts with the metal on the interface, causing polarization of the cell.

84033 5 5 1 ί - ^ -3-

This creates a deviation in the cell, the magnitude of which is unknown.

Therefore, there is a problem with the reliability of the measurements over a long period of time and heretofore this problem has been overcome by frequent replacement of the oxygen cell. However, this is not a satisfactory solution due to possible interruptions of the process in question and due to the associated problems in the replacement operations, not to mention the cost of the device which, although not huge, is nevertheless noticeable, especially for the gas supply type.

The object of the present invention is to solve this problem by providing an improved type of oxygen cell that is completely reliable over a long time. The cell 15 is also very sensitive, so that it can be placed in any position with respect to the measuring and signal recording instruments, and moreover its cost is limited.

The present invention is an apparatus for measuring the oxygen concentration in liquid media at high temperature, whereby this concentration is obtained as unknown partial oxygen pressure, by measuring the emk of a concentration cell, characterized by generating the known partial pressure of oxygen with a substance which reacts with oxygen to form compounds which are easily removed from the reaction medium.

This material should preferably give gaseous reaction products with oxygen, or else it should be liquid at the operating temperature and give reaction products which may be solid but float on the liquid medium.

Examples of such materials are any elements which can react with oxygen to form volatile products or which, despite giving solid reaction products, have a melting point lower than the temperature at which the operations are carried out, such as, for example, aluminum , antimony, bismuth, carbon, lead, alkaline earth metals, 84033 5 5 ί »'-¾ -4- ΟΠΙ, phosphorus, sulfur, tin, etc. Obviously for various reasons the choice is limited, such as the element's extraordinary reactivity the pollutant effect thereof or the risks caused thereby or of the reaction products thereof.

The present invention will be described hereinafter by means of one of its embodiments, illustrated in the accompanying drawing, by way of example only, without limiting the objects or requirements of the invention.

The drawing shows a chamber with zirconia walls 1, with a lid 2, filled with the reactive substance 3, as described above.

The electrodes 8 and 6 are fixed with their insulated electric wires 9 and 5 on the outer and inner sides 15 of the wall 1. The internal electric wire 5 leaves the chamber through the narrow opening 4 (which also serves to extract the gaseous products of the reaction) in the lid 2, which also preferably has a second opening 11, where the wires 9 and 10 of a thermocouple pass, the weld 12 of which is fixed as close as possible to the electrode 6 and wall 1.

This placement of the thermocouple is useful to ensure the best possible measurement of the temperature of the oxidation reaction taking place in the vicinity of the electrodes. For each reaction temperature there is an accurate oxygen partial pressure which is used as the reference value Pn

U2R

in Nernst's equation, mentioned earlier.

In operation, a milk is fed between electrodes 6 and 8

P P

formed by the difference between 22R and 22Xr where ^3da the latter is obtained by measuring the emk at the end points of the leads 5 and 7, when the temperature is known.

Various oxygen cell prototypes of the present invention have been formed and tested under industrial conditions. Trials were successfully performed without interruption for three months.

The signal delivered by the cell during use has been found to be completely independent of the age of the cell and it has also been observed that there are no particular limitations as to the successive locations of the cell), the recording and measuring instruments.

Of the numerous elements used for generating the partial reference oxygen pressure, lead, tin, carbon and sulfur have given the best results. Currently, however, the greatest reliability, in the complete absence of any type of problems and the highest sensitivity, is obtained with tin and carbon, 1 x 10 atm. the lower limit of the measured concentration is obtained, determined with the mass spectrometer and with H2 / H20 gas mixtures with a known oxygen content.

840 33 5 5

Claims (5)

An apparatus for measuring the concentration of oxygen in liquid media at a high temperature, consisting of an oxygen concentration cell, in which an electromotive force is generated between two. electrodes, one of which is in contact with the high temperature liquid medium containing an unknown oxygen concentration and the other being in an environment of known oxygen concentration formed by reaction between oxygen and a reactive substance in a chamber with walls permeable to acidic ions, characterized in that the substance which reacts with oxygenated products forms which are easily removed from the reaction medium in the chamber. 2. Device according to claim 1, characterized in that the substance is an element which forms gaseous products by reaction with oxygen. The device according to claim 1, characterized in that the substance is liquid at the temperature of the liquid medium, and by reaction with oxygen forms solid products which easily form slag. 4. Device according to claim 2, characterized in that the material is selected from carbon and sulfur. Device according to claim 3, characterized in that the material is selected from lead and tin. # «84033 5 5