DE102006031040A1 - Mercury measuring method for use during e.g. waste incineration, involves splitting mercury compounds to obtain atomic mercury, whose concentration is measured by photometer, where gas comes into contact with boron compounds - Google Patents

Abstract

The method involves splitting mercury compounds in burnt gas by a splitting device (16) e.g. boric thermo-catalytic filter, to obtain atomic mercury, whose concentration is measured by a photometer (18). The gas comes into contact with boric materials, with exclusion of boron nitride, and with boron compounds e.g. titanium diboride, magnesium diboride, boron carbide, ferroboron, lanthanum hexaboride and boron trioxide, for splitting the mercury compounds. The boric materials and/or boron compounds are heated on temperatures in a range of 200 to 500 degrees centigrade. An independent claim is also included for a device for measuring mercury in a gas.

Description

The This invention relates to methods and apparatus for measuring mercury in gases that break down mercury compounds, to obtain atomic mercury, its concentration measured becomes.

Such methods and devices are for. B. from the DE 37 04 533 A1 known.

in the Flue gas from incinerators often occurs in a variety of mercury bound states on. For reasons Environmental protection is a continuous monitoring of emissions and Immissions required. To the total mercury concentration in the flue gas to determine the mercury is in one and the same chemical State brought and for this atomic mercury has proved to be suitable, its concentration is easy to measure with particular spectroscopic means, in particular with an atomic absorption spectrometer.

In the flue gas matrix enters mercury z. B. as mercuric chloride on, but also in elementary form, dust-bound and in others Mercury compounds.

Alles these manifestations of mercury must be in atomic (elementary) Mercury be transferred, afterwards to allow a quantitative concentration measurement, the sufficiently accurate Statements about Emission and / or immission values allows. For this transfer of mercury from the chemical and physical manifestations occurring in the flue gas In atomic mercury, the term "splitting" is used below Already present in atomic form, mercury remains unchanged.

The state of the art, cf. For example, US 5,879,948 requires temperatures above 800 ° C in the decomposition reactor. At such high temperatures, the process control is not only expensive, but also with regard to the accuracy and reproducibility of the measurement results highly prone to failure. The WO 2005/029044 A1 teaches the use of silicon carbide or boron nitride for the thermal decomposition of mercury-containing gases.

Of the Invention is based on the object, a method and an apparatus with which mercury in gases, in particular flue gases, preferably exactly and with as possible low effort is measurable.

For this teaches the invention, the gas (flue gas) for splitting with boron-containing To bring material into contact. Bornite ferrite (BN) is a splitting material little suitable. BN is a material that in particular because of its great hardness used for coating drills and tools. Also at higher Temperatures, this material is not removed by oxidation (i.e., the mass changes not).

The boron-containing materials or boron used according to the present invention, however, are a strong reducing agent at high temperatures. The boron reacts with the oxygen from the flue gas and forms boron trioxide (B ₂ O ₃ ). The boron dioxide formed is continuously removed by the gas stream and can be precipitated in particular at the hose which leads away from the high-temperature catalyst region. To avoid such a precipitate, it is provided according to an embodiment of the invention to meter in a liquid after the splitting of the gas stream. As a liquid, in particular water is suitable.

By the removal of the for the catalytic cleavage action is harmful boron trioxide layer practically constantly a fresh effective catalytic surface with boron available. at Use of boron nitrite (BN), however, there is a poisoning of the Catalyst by chemical substances contained in the flue gas, i.e. the surfaces are passivated.

The boron-containing material is preferably used in granular form and can, for. Example, consist of the element boron and / or a boron compound, wherein the following boron compounds have been found to be well suited: TiB ₂ , MgB ₂ , B ₄ C, B ₂ O ₃ , ferroboron, lanthanum hexaboride.

The Flue gas is thus, if necessary, after treatment with ultrafine filters, brought into contact with the boron or a boron compound to the above to cause the described splitting into atomic mercury.

One decisive advantage of the invention is that for this Splitting process the boron or the said boron compound as Catalyst can be heated only at relatively moderate temperatures got to. Good efficiencies for the reaction already occurs at temperatures of 190 ° C. Prefers becomes in a temperature range of the boron-containing catalyst from 200 to 500 ° C worked.

The relatively low temperatures compared to the prior art for the thermocatalytic process make it possible to obtain relatively accurate, easily reproducible measurement results with low susceptibility to measurement and with relative ease simple and inexpensive control means.

The The present invention preferably contemplates the use of boron in substantially pure form or boron in the form without a covalent bond.

A preferred embodiment of the invention provides that the examined Flue gas is diluted before contact with the boron-containing thermocatalyst, especially with a critical nozzle, which ensures a constant dilution ratio. The dilution the flue gas can z. B. with air in the ratio 1 : 50 (flue gas: air).

In front the dilution Preferably, ultrafine filters are placed in the flue gas stream to Withhold dust. In this case, mercury bonded to dust is heated by high temperatures of the ultrafine filter released.

Prefers are doing the one or the finest filter, the critical nozzle for the dilution and boron-containing thermocatalyst at a common temperature held.

A Another variant of the invention provides that in the flow of the process gas behind the boron-containing thermocatalyst, a liquid is added, for. As water or a diluted Acid. With that you can Deposits on the gas-carrying Walls avoided become. The added liquid can then, before the gas flow reaches the photometer, with a Separators are removed from the process gas.

A Another variant of the invention provides that in the flow of the process gas after the boron-containing thermocatalyst and especially directly one or more filters are placed in front of the photometer to to retain possibly occurring reaction products.

The Invention may, for. B. be used in waste incineration, sewage sludge incineration, in coal-fired power plants, in special waste incineration, in thermal Floor cleaning and also in the processing of metal scrap.

The The invention also includes devices for measuring mercury in gases by means of which the above-mentioned process conditions are realized.

Further preferred embodiments of the method and the device according to the invention can be found in the dependent claims.

following Be exemplary embodiments of Invention with reference to the drawing described.

The 1 to 3 show different embodiments of devices for measuring mercury in gases.

In The figures are mutually corresponding or functionally similar Components provided with the same reference numerals.

In the embodiment of an apparatus for measuring mercury in flue gases according to 1 is using a sample probe 10 continuously extracts a gas stream of flue gas. Dust contained in the flue gas matrix is passed through a heated microfilter 12 retained from the gas stream. This is the finest filter 12 maintained at temperatures at which mercury bonded to dust is released, which then remains in the gas stream.

With a heated critical nozzle 14 If the gas flow with a factor greater than 10, in particular greater than 30 and more particularly greater than 40, z. B. 1: 50, with a gas, z. As air diluted.

Subsequently, the gas flow through a splitter 16 guided. In the splitter 16 is a boron-containing granules and the gas stream passes through the granules with a large contact surface for the catalytic conversion of the mercury present in the gas stream into atomic (elemental) form.

One with the reference numeral 20 indicated high-temperature range detected either - as shown - the micro-filter, the dilution nozzle and the boron-containing thermocatalyst or only the latter two components, in which case the micro-filter is kept at a lower, but compared to the ambient temperature elevated temperature.

The mercury in atomic form containing gas stream is then in a photometer 18 headed, where with z. B. atomic absorption spectroscopy, the concentration of mercury is measured.

2 shows a modified device for measuring mercury in gases, in which compared to the embodiment according to 1 the gas dilution is omitted, but also in this embodiment, a Gasverdünnungseinrichtung 14 (as in relation to 1 described) may be provided.

The embodiment according to 2 differs from the example according to 1 thereby, that one device 22 in the gas stream behind the splitter 16 is provided to supply a liquid to the gas stream. This embodiment is particularly suitable for measurements on a flue gas matrix at z. As cement plants, where there are deposits on the gas outlet of the high temperature range 20 can come. The metered addition of a liquid into the gas stream can have a cleaning effect and avoid deposits and deposits on the gas flow-carrying walls. As a liquid comes z. As H ₂ O or a dilute acid into consideration. The added liquid is with a separator 24 removed from the gas stream before this the photometer 18 reached. As a liquid separator z. B. be provided a Peltier cooler.

At the in 3 In the embodiment shown of an apparatus for measuring mercury in gases, the boron-containing thermocatalytic material is used in the form of a sintered frit.

The sample probe 10 is - as in the embodiments according to the 1 and 2 - Heated and the flue gas is heated by superfine filters 12 sucked where the operations described above take place. The splitting device 16 in the form of the boron-containing thermocatalytic filter has a porous structure and thus a very large contact area with minimal flow resistance.

In the gas stream behind the splitter 16 a filter is arranged to retain any occurring reaction products.

When related to the description of the 1 . 2 and 3 a filter is mentioned, this can also be staggered in each case several filters in a row.

The in the 1 . 2 and 3 shown and described above individual elements (filter, dilution nozzle, liquid addition means, separators, etc.), different from those in the 1 . 2 and 3 specifically illustrated embodiments are each optionally combined, for. B. can the filter 26 according to 3 in the embodiments according to the 1 and 2 be used and the dilution device 14 according to 1 can also in the other two embodiments according to the 2 and 3 be used.

Claims (19)

A method of measuring mercury in gases, wherein mercury compounds are split to obtain atomic mercury whose concentration is measured, characterized in that the gas is brought into contact with boron-containing material, with the exception of BN, for decomposition. Method according to claim 1, characterized in that that the boron-containing material is essentially boron. Method for measuring mercury in gases, in which mercury compounds are split in order to obtain atomic mercury, the concentration of which is measured, characterized in that the gas is brought into contact with one of the following boron compounds for decomposition: TiB ₂ , MgB ₂ , B ₄ C, B ₂ O ₃ , ferroboron, lanthanum hexaboride. Method according to one of the preceding claims, characterized characterized in that boron-containing material or the boron compound is used in granular form. Method according to one of the preceding claims, characterized characterized in that after the splitting a liquid is added to the gas. Method according to one of the preceding claims, characterized characterized in that the method is carried out continuously. Method according to one of the preceding claims, characterized in that the boron-containing material or the boron compound is heated to temperatures in the range of 200 to 500 ° C. Method according to one of the preceding claims, characterized in that the boron-containing material or the boron compound to below 300 ° C is heated. Method according to one of the preceding claims, characterized characterized in that the gas prior to its contact with the boron-containing Material or the boron compound is diluted. Method according to one of the preceding claims, characterized characterized in that the measurement of the concentration of the atomic Mercury is carried out with a photometer. Use of boron-containing material for the decomposition of mercury compounds in flue gases. Use according to claim 11 with the features of claims 1 to 10. Device for measuring mercury in gases, with a splitting device ( 16 ) in order to bring mercury contained in the gases into atomic form and with a measuring device ( 18 ) for measuring atomic mercury, characterized in that the splitting device ( 16 ) borhalti ges material except BN, with which the mercury compounds containing gas is brought into contact. The device of claim 13, wherein the boron-containing Material is essentially boron. Device for measuring mercury in gases, with a splitting device ( 16 ) in order to bring mercury contained in the gases into atomic form, and with a measuring device ( 18 ) Measuring atomic mercury, characterized in that the splitting device ( 16 ) has one or more of the following boron compounds: TiB ₂ , MgB ₂ , B ₄ C, B ₂ O ₃ , ferroboron, lanthanum hexaboride. Device according to one of claims 13 to 15, characterized that boron-containing material or the boron compound in granular form is present. Device according to one of claims 13 to 16, characterized in that in the flow path behind the splitting device ( 16 ) a liquid addition device ( 22 ) is arranged. Device according to one of claims 13 to 17, characterized in that means are provided to a continuous gas flow from a sampling probe ( 10 ) to a measuring device ( 18 ) for atomic mercury. Device according to one of claims 13 to 18, characterized that means are provided to the boron-containing material or the Boron compound on temperatures above 190 ° C too heat, in particular temperatures above 200 ° C, in particular temperatures in the range of 200 to 500 ° C.