FI70327B - SAETT ATT ANALYSIS IN GASKOMPOSITION - Google Patents

Description

70327

This invention relates to a method of analyzing a gas mixture which may contain dusty solids by separating and passing a predetermined amount of the gas mixture along a sampling channel for analysis, mixing a known amount of liquid into the separated gas mixture to absorb the gas mixture and analyzing the gas mixture absorbing liquid.

It is already known to measure the dust content of flue gases by taking a sample of the flue gases at appropriate intervals and analyzing the dust content of this sample.

It is also known to continuously measure the dust content of flue gases by means of light optics, which, however, provides only indicative information on the amount of dust.

German application 27 23 310 further discloses a method and apparatus for continuous gas analysis by absorbing a gas into a flowing liquid and measuring the ions absorbed from the gas into the liquid by an ion-sensitive electrode, the absorption liquid being mixed as a fine mist with the gas just before the measurement, the liquid phase separated from the gas and passed through.

However, it is not possible to analyze dusty gases with this previously known method and apparatus. In the device, the sample gas has to enter the absorption point dry over the entire length of the sampling line, which may in practice be several meters long. In such a situation, any dust accumulates during the measurement on the walls of the duct, from which it must be washed into the sample set 2 70327 for analysis when measuring the amount of dust and components and causing flow disturbances in sampling, preventing e.g. realization of the isokinetics of sampling.

In the solution of the publication, the absorption takes place in a liquid jet, whereby the residence time of the sample gas in the absorption as well as the absorption surface is quite poor and the absorption is thus realized from a very imperfect. In this case, it is not possible to measure the quantitative values of the substances, but one has to confine oneself to indicating whether or not a substance is possibly among the gas mixture to be measured. In addition, gases present in very low concentrations as well as poorly absorbed gases go unnoticed because they do not have time to be absorbed into detectable concentrations in the liquid due to the short absorption time.

It is an object of the present invention to provide a method which makes it possible, even continuously, to measure the components of a gas mixture which may contain dusty solids both qualitatively and quantitatively and in particular a method for continuously measuring the Glauber salt content of recovery boiler flue gases.

In the description of the application and the claims, it is meant by analyzing the gaseous mixture, possibly containing a dusty solid, by analyzing the gaseous components of the gas mixture and / or the various solid components in dusty form. Correspondingly, a gas mixture means a combination of at least two gaseous substances or at least one gaseous substance and at least one solid.

The main features of the invention appear from the appended claims.

According to the present invention, a small gas flow isokinetically separated from the gas stream to be analyzed or from a large amount of gas into the sampling channel and passed for analysis along the sampling channel. Immediately after the gas flow 70327 has been separated, i.e. immediately at the mouth of the sampling channel, a liquid is mixed into the gas flow, e.g. by injecting it into the sampling channel from the slit-like channel surrounding its mouth, the liquid forming a uniform film-like surface in the transverse direction of the sampling channel. On the one hand, the liquid and the gas mix with each other, whereby absorption begins to take place immediately and, on the other hand, form alternating periods in the sampling channel so that the liquid forms plugs with space between the gases. After the liquid and gas in this manner flows up to tens of meters long sampling channel analysis device gets absorption take place as completely as possible while flowing along the channel the fluid will see to it that any dusty particles are washed along the channel side will not remain in the channel walls to block the channel and to mix the measurement.

Given the flow rate of the liquid to be mixed per unit time and the amount of gas flowing to the analysis per unit time, components for which the method of analysis is known can be easily determined as a continuous measurement of the absorption fluid and further calculated based on certain factors and analytical values.

If it is desired to measure an average over a period of time, the same absorption liquid can be circulated in the apparatus, whereby the concentration of the liquid with respect to the absorbed component increases all the time. The total amount of component absorbed divided by the measured amount of gas would thus give the average concentration of the measurement time.

One application of continuous concentration measurement is the measurement of the Glauber salt content of the flue gases of a recovery boiler in a continuous display. In this case, the object of the measurement is a highly water-soluble salt, the concentration of which in the water can be measured with a pair of Na-specific electrodes in a liquid flow.

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The solids and gases are preferably separated from the water stream before it is analyzed, so that its sodium ion content can be measured from the water stream with a sodium ion-specific electrode.

The water used as the absorption liquid is introduced into the sampling space, such as the sampling point of the sampling probe, to ensure that the sampling opening remains open and so that all the water enters the sampling space under the influence of the vacuum therein.

The water flow can be analyzed with a sodium ion-selective electrode or other measuring device known per se, such as, for example, a continuous flame photometer or by performing turbidimetric sulphate analysis.

In the manner according to the invention, the Glauber salinity profile of the flue gases of the recovery boiler at the flue gas duct can be continuously monitored. The invention provides immediate information on the Glauber salinity at various points in the channel, as well as information on the effect of, for example, sooting or the rattling of electrostatic precipitators on dust emissions.

The invention will be described in more detail below with reference to the accompanying drawing, which schematically shows an apparatus for applying the method according to the present invention applied to the measurement of the Glauber salt content of a recovery boiler.

In the drawing, the flue gas duct is marked with the reference number 1. The sample gas 2 is sucked at a certain speed through a special sampling probe 4. The inner surface of the probe is washed with a continuous jet of water which is passed through a pipe 5 to the sampling end of the sampling probe 4 so that all water enters the sampling probe 4 to wash the sample gas with water and rinse the inner surface 8 is separated from the water stream 9, which is led to the next separation device 5 70327 10, where the gases 12 are separated from the water stream 13 and pumped out by a pump 11. The water stream 13 is led to a measuring cell 14, where the concentration of sodium ions is continuously measured by means of a sodium ion-specific eLectrode. The concentration of sodium ions is observed as the electrode potential using a plotter. The amount of sample gas 2, the amount of scrubbing solution 5 and the measured sodium ion concentration can be used to calculate the Glauber salt concentration of the flue gases at each moment.

Finally, the water stream 15 is led to a sewer or back to the process.

The invention is in no way limited to the above example, but is suitable for use in all kinds of gas analysis, such as studying urban air pollution and the accumulation or continuous monitoring of the amount of various substances and gas components, e.g. in places where a particular component or components may have a significant effect.

Claims (8)

70327 A method for analyzing a gas mixture containing possibly dusty solids by separating and passing a predetermined amount (2) of the gas mixture along the sampling channel (4) for analysis, mixing a known amount of liquid (5) to absorb the gas mixture into the liquid and analyzing the gas mixture that the liquid (5) is mixed with the separated gas mixture to be analyzed immediately after it is separated and that said separated gas mixture and liquid are passed substantially together along the sampling channel (4) for analysis to keep the channel (4) free of possible solids and to maximize the absorption time of said gas mixture; between the analysis of the liquid absorbed by the gas mixture. A method according to claim 1, characterized in that in order to continuously mix the separated gas mixture (2) according to a predetermined flow rate into the liquid, a new liquid of known flow rate is continuously fed to the sampling channel for continuous analysis. A method according to claim 1, characterized in that a certain amount of liquid is recycled for a certain time by re-feeding it into the sampling channel to analyze the accumulation of gas mixture for said time. Method according to one of Claims 1 to 3, characterized in that any liquid-insoluble solids (8) and non-absorbable gases (12) are separated (7, 10) from the liquid (5) before it is analyzed (14). Method according to one of the preceding claims, characterized in that the analysis (14) is carried out periodically on the liquid accumulated between the periods and preferably in such a way that any liquid-insoluble solids (8) and non-absorbable gases (12) are thus separated (7, 10). accumulated fluid only shortly before its analysis (14). Method according to one of the preceding claims, characterized in that the liquid to be fed is kept at substantially the same temperature. Method for analyzing the Glauber salt content of the flue gases of a recovery boiler according to one of the preceding claims, characterized in that water is used as the liquid and that its sodium content is measured (14) on the water with a sodium-specific electrode. Method according to one of the preceding claims, characterized in that the liquid (5) is mixed with the separated gas mixture (2) by spraying it into the sampling channel (4) in its transverse direction as a film-like spray around substantially the entire sampling channel (4). 8 70327