DE102007004034A1 - Gas-steam-mixture producing method for use as e.g. calibrating gas, involves combining partial stream containing elementary mercury with partial stream containing ionic mercury and transferring steam mixture into consumer device - Google Patents

Abstract

The method involves dividing a gas-vapor-mixture stream containing ionic mercury into partial streams (T1, T2) after discharge from an evaporator (5), and transferring the stream (T1) into a converter (21) for contacting a catalyst i.e. red brass, in the converter for producing elementary mercury. The stream (T1) containing elementary mercury is combined with the stream (T2) containing ionic mercury downstream to the converter. The gas-steam mixture containing ionic mercury and elementary mercury is transferred into a consumer device (11). An independent claim is also included for a device for producing a gas-steam-mixture containing ionic mercury and elementary mercury.

Description

The The invention relates to a process for producing a gas-vapor mixture according to claim 1 and an apparatus for carrying out the Method according to claim 6.

The Emission of mercury in elemental, metallic, ionic or form attached to dust particles poses a known problem that is the burning of waste and fossil fuels arises. From the prior art, therefore, a number of and flue gas cleaning processes and apparatus known in the art Release of mercury in all occurring To reduce species.

In order to test and monitor the effectiveness of the flue gas and flue gas cleaning devices, continuous atomic absorption spectrometry or fluorescence spectrometry based emission measurement and analysis systems have been developed. However, only elemental mercury can be detected with these photometric methods, so that always an upstream reduction stage is required to all non-elemental species such. B. ionically bound mercury (HgCl ₂ ) to convert into elemental mercury.

therefore is a quantitative analysis of the reduction required with appropriate calibration and, if necessary, recalibration the photometric analyzer to the flue gas cleaning qualify and quantify in terms of mercury species to be able to.

In order to meet these requirements, the IAS GmbH, Frankfurt am Main, Germany, opened its doors EP 0 923 985 B1 based calibration gas generator developed. This generated by evaporation of mercury salt solutions such. As mercuric chloride HgCl ₂ , which is stabilized with hydrochloric acid HCl, ionically bound mercury as gas-vapor mixture in a definable concentration. This mainly produces ionic mercury and only small amounts of elemental mercury. However, existing analysis tasks often require a higher level of elemental mercury. Moreover, there is interest in producing a defined mixture of elemental and ionic mercury in the calibration gas in order to be able to simulate the conditions in the actual flue gas.

aim The invention is therefore, these and other disadvantages of the prior to overcome technology and a device and a To provide a process for producing a gas-vapor mixture, that besides ionic mercury also a not negligible Contains amount of elemental mercury. The composition of the gas-vapor mixture, in particular the ratio of ionic to elemental mercury should be exactly definable and be reproducible. The aim is also a simple and cost-effective construction, the light and reliable to handle.

main features The invention are set out in claim 1, claim 6 and claim 30. refinements are the subject matter of claims 2 to 5 and 7 to 29.

• • Teilen eines Gas-Dampf-Gemischstromes enthaltend ionisches Quecksilber nach Austritt aus einem Verdampfer in einen ersten Teilstrom und in einen zweiten Teilstrom,
• • Überführen des ersten Teilstroms in einen Konverter,
• • Kontaktieren des ersten Teilstroms mit einem in dem Konverter vorgesehenen Katalysator zur Erzeugung von elementarem Quecksilber,
• • Vereinigen des ersten Teilstroms enthaltend elementares Quecksilber mit dem zweiten Teilstrom enthaltend ionisches Quecksilber stromabwärts des Konverters,
• • Überführen des Gas-Dampf-Gemisches enthaltend ionisches Quecksilber und elementares Quecksilber in eine Verbrauchervorrichtung.

In a method for producing a gas-vapor mixture containing ionic mercury and elemental mercury, the following steps are provided according to the invention:

• Dividing a gas-vapor mixture stream containing ionic mercury after leaving an evaporator into a first substream and into a second substream,
• Transferring the first substream into a converter,
• Contacting the first substream with a converter provided in the catalyst for the production of elemental mercury,
• Uniting the first substream containing elemental mercury with the second substream containing ionic mercury downstream of the converter,
• Transferring the gas-vapor mixture containing ionic mercury and elemental mercury into a consumer device.

One such process is inexpensive by simple means to realize; Moreover, the ratio can be between ionic and elemental cross silver extreme set precisely so that generates a gas-vapor mixture which has an always defined composition. By the distribution of the gas-vapor mixture generated in the evaporator with ionic mercury in two sub-streams it is possible to lead one of the partial streams into a converter, to convert the ionic mercury into elemental mercury. Subsequently, both partial streams are returned to defined quantities, so that almost any mixing ratio between ionic and elemental mercury.

With ionically bound mercury, the reduction stage of a mercury emission measurement system can be tested, and also the sampling and forwarding from the flue gas channel to the analyzer or its reduction stage. However, mercury (II) chloride, in contrast to elemental mercury, is a component which strongly adsorbs to surfaces. This can therefore be due to insufficient heating of sampling and Management system greatly affect the actual measurement that the expected value can not be achieved by wall losses.

A On the other hand, testing with elemental mercury does not cover either the sampling still the reduction system, since elemental mercury has only very low adsorption effects and the measurement by the photometric method is directly accessible. The Testing with elemental and ionic mercury offers hence the possibility of analyzer and sample preparation and removal separately and thus also on demand to run a fault analysis.

The The invention further provides that the first partial flow before and / or after the converter is adjustable and / or adjustable while the second partial flow in addition or alternatively a restriction device is supplied. The latter generated in the evaporator outlet a back pressure, so that the gas-vapor mixture within the first Branching divides into two sub-streams. Elaborate valve or throttle bodies are therefore not required, which is a cost-effective apparatus implementation of the method allows. Further can the composition of the gas-vapor mixture, in particular the ratio of ionic to elemental Mercury, always exactly defined and reproducible.

Around to achieve optimal conversion results in the converter, the catalyst is generated during the conversion reaction a temperature in the range of 100 ° C to 500 ° C, preferably in the range of 120 ° C to 250 ° C, heated, which is also feasible with little control effort.

Of the Catalyst is preferably a copper-containing catalyst compound, especially a gunmetal.

• • einen Verdampfer, dessen Verdampferkammer mit einer Verdampferauslassleitung verbunden ist,
• • eine erste Verzweigung, mittels der ein von dem Verdampfer in die Verdampferauslassleitung überführter Gas-Dampf-Strom in einen ersten Teilstrom und in einen zweiten Teilstrom aufteilbar ist, und
• • einen Konverter, geeignet zur Darstellung von elementarem Quecksilber, der mit einer Konverterauslassleitung verbunden ist,
• • wobei der Konverter derart mit der Verzweigung der Verdampferauslassleitung in Strömungsverbindung steht, dass der erste Teilstrom des Gas-Dampf-Stroms in den Konverter überführbar ist, und
• • wobei die Konverterauslassleitung in einer zweiten Verzweigung mündet, welche den von dem Konverter in die Konverterauslassleitung überführten ersten Teilstrom und den zweiten Teilstrom des Gas-Dampf-Stromes zu dem Gas-Dampf-Gemisch enthaltend ionisches Quecksilber und elementares Quecksilber vereinigt.

An apparatus for producing a gas-vapor mixture containing ionic mercury and elemental mercury, in particular for carrying out the method according to the invention, has according to the invention

• An evaporator whose evaporator chamber is connected to an evaporator outlet line,
• A first branch, by means of which a gas-vapor stream transferred from the evaporator into the evaporator outlet line can be divided into a first partial stream and into a second partial stream, and
• A converter suitable for displaying elemental mercury connected to a converter outlet line,
• Wherein the converter is so in flow communication with the branch of the evaporator outlet, that the first partial flow of the gas-steam stream is convertible into the converter, and
• Wherein the converter outlet line terminates in a second branch which combines the first sub-stream transferred from the converter into the converter outlet line and the second sub-stream of the gas-vapor stream to the gas-vapor mixture containing ionic mercury and elemental mercury.

With This device can be without much effort produce a gas-vapor mixture that has an always-defined composition has, in particular an always reproducible ratio from ionic to elemental mercury. In the converter will advantageously reduced ionic mercury to elemental mercury.

Of the Evaporator and the converter are through the evaporator outlet connected with each other. The latter has a branch behind the evaporator on, so that a partial stream of the gas-steam mixture, which at first predominantly ionic Cross silver contains, from the evaporator outlet in the converter can be transferred. The second or remaining partial flow flows unchanged further. The converted gas-vapor mixture exhibits mercury now only in elemental form, while the unconverted substream continues to be ionic mercury contains. By combining the two partial flows can now be within the second branch always defined generate composite gas-steam mixture.

Of the Evaporator is preferably part of a metered-evaporator system, the at least one metering pump, a gas flow regulator and the evaporator having. This can already be done during dosing and the evaporation in the evaporator advantageous events for optimal Adjustment of mercury salt contents in the gas-steam mixture to be hit. The dosing evaporator system is also suitable a gas-vapor mixture having a temperature in the range of 160 ° C to provide 200 ° C, preferably 180 ° C, which has a favorable effect on further processing or use.

The converter is suitably heated to achieve ideal conversion temperatures during the reduction. Further embodiments relate to the use of metals or metal alloys as a catalyst, which may comprise copper, zinc, tin and / or lead, wherein suitably the metal alloy "gunmetal" CuSn7ZnPb can be used, which has a porous, gas-permeable surface and thus over one before Partly has large capacity and service life. The catalyst may be present in the converter, for example, as a packing, packing, wire mesh, foil or sintered material.

A Development of the invention provides that the converter component a generator. This has at least one gas cooler, a gas flow regulator and the converter, these being preferred are connected in series and via the converter outlet in fluid communication. The gas cooler lowers the temperature of the partial flow T1, which after flowing through the converter contains only elemental mercury. Subsequently, the partial flow with the gas flow regulator precisely metered and in the second branch the second partial flow be mixed with the ionic mercury.

Of the Converter has an inlet opening, in which the first branch opens while the gas flow regulator has an outlet opening via the converter outlet in the second branch opens.

In the evaporator outlet line is for adjustment and / or regulation the second partial stream downstream of a restriction device provided, suitable for throttling the second partial flow. she is preferred between the first branch and the second branch arranged and formed as a heated capillary. She further points expedient a larger flow resistance on as the converter and / or the generator, so that within the evaporator outlet line creates a back pressure. This will be achieved advantageous that the merger of the two Partial flows can be controlled so that a correspondingly high or low concentration of ionic mercury in the gas-vapor mixture can be fed. With the latter can therefore also Analysis tasks are performed, the higher Require fraction of elemental mercury in the test gas.

The Gas-vapor mixture can be supplied to at least one consumer device, For example, an analyzer in which the gas-vapor mixture is used as calibration or test gas.

Of the Evaporator preferably provides a gas-vapor mixture with a proportion of ionic mercury in the range of 95% to 100%, preferably in the range of 98% to 100%, for feeding into the evaporator outlet line ready. Therefore, you passed over the entire gas-steam mixture the first branch through the converter, can be Reach concentrations of elemental mercury of up to 100%. Other conditions can be adjusted easily at any time.

constructive it is favorable if the first and / or the second branching are formed by tees that act as valves or at Need to be complementarily or alternatively equipped with flow regulators can.

A Another embodiment provides that the evaporator and the converter arranged in a common housing are. This results in an extremely compact Design that is cost-effective to implement and simple to handle. The case may be beyond a removal opening for replacement of the converter and / or of the catalyst, so that the maintenance with little apparativem Effort can be made. Furthermore, in the compact arrangement, the flow paths especially short, and heating the converter material for catalysis can be timely with the heating for evaporation purposes done so that a particularly economical working Device is present.

One Another aspect of the invention, for the self-employed Protection is claimed, the use of a gunmetal looks like Catalyst in a device for producing a gas-vapor mixture, Contains ionic and elemental mercury.

Further Features, details and advantages of the invention will become apparent the wording of the claims and the description below of embodiments with reference to the drawings. Show it:

1 a schematic representation of an apparatus according to the invention for producing a gas-vapor mixture,

1a a schematic representation of a tee for a branch,

2 a picture section 1 with detailed representation of the generator and

3 a schematic representation of an evaporator-converter compact unit

Basically, the invention relates to an apparatus for producing a defined composition of a gas-vapor mixture containing ionic and elemental mercury in a desired ratio to one another. The apparatus therefore comprises an evaporator chamber in which a mercury salt solution is evaporated to obtain a gas-vapor mixture. In this gas-vapor mixture, approximately 100% of mercury is present as an ionic compound when the mercury salt solution within the evaporator chamber is vaporized to corresponding physical conditions. Basically, the representation of such Gas-vapor mixtures known in the art.

The Evaporator chamber is according to the invention with a Evaporator outlet in fluid communication to the Remove gas-vapor mixture from the evaporator chamber and at least partially to be able to perform a converter. This is suitable to ionic mercury (Hg, ion) in elementary To reduce mercury (Hg, el). He is also with a converter outlet connected to the gas-vapor mixture, in which now mercury is present to approximately 100% as elemental mercury, remove from the converter. From the gas-steam mixture from the evaporator chamber is preferably via a first, Branch provided in the evaporator outlet line a first Partial branched off and fed to the converter. The rest Gas-vapor mixture remains in the evaporator outlet. The gas-steam mixture is thus divided into two streams, the first Partial flow in the converter is reduced, while the second Partial flow is subjected to any change. The latter therefore contains mercury in its ionic Shape. The discharged from the converter first partial flow, which now contains elemental mercury is in a second branch in the desired dosage again the second substream admixed, so that the combined gas-steam mixture both ionic mercury (Hg, ion) and elemental mercury (Hg, el) with well-defined proportions.

1 shows a device according to the invention with an evaporator chamber 5 in a dosing evaporator system 1 is arranged. Such a system is distributed by the IAS GmbH, Frankfurt under the name "HoVaCal" as a calibration gas generator This arrangement comprises a metering pump 3 , a gas flow regulator 4 and an evaporator 5 that have appropriate connection lines 6 . 7 connected to each other. With this arrangement, an about 180 ° C hot gas-steam mixture can be prepared by evaporating aqueous mercury salt solutions such as mercury (II) chloride solutions and admixing a carrier gas such as nitrogen or air. In principle, the temperature can also be selected higher or lower by about 20 ° C.

The emerging from the evaporator hot and loaded with water vapor mercury chloride gas vapor is now in an evaporator outlet 8th led a branch 8th'' for dividing the fluid into a first partial flow and a second partial flow. This allows a first partial flow on the continuation 8th' the evaporator outlet are led into the converter.

In 2 is the converter 21 as part of the generator 2 shown. The generator 2 settles out of the heated converter 21 , filled with catalyst material, a gas cooler 22 and a gas flow regulator 23 together. The order of placement is important to avoid adsorption losses of ionic mercury that is already being fed to the heated converter chamber while hot. The components of the generator 2 are over the line 9 ' in fluid communication with each other; the pipe is also called converter outlet pipe 9 designated.

The from the converter 21 escaping gas stream is laden with elemental mercury and also hot and humid; therefore this must be cooled and dried. This task is performed by the downstream gas cooler 22 , A loss of mercury in the test gas is not to be feared because the elemental mercury shows no adsorption or water solubility. The cooling and condensation of the gas vapor mixture immediately after the converter 21 is helpful because it avoids re-reactions with the still in the gas phase hydrochloric acid, coming from the evaporation phase, avoided.

The thus dried and cooled mercury-containing fluid or now gas can the gas flow regulator 23 be fed so that the set gas flow a defined proportion of elemental mercury generator 2 leaves.

The second part stream, also from the evaporator leaked hot and steam-laden mercury chloride gas-vapor mixture, by the branching 8th'' on the converter 21 passed, there is a restriction device, in this case a heated capillary 10 , which is dimensioned so that the flow resistance for all gas flows is sufficiently higher than by the generator 1 ,

The two partial gas streams are downstream of the generator at a second branch 9 '' reunited.

The branches 8th'' . 9 '' 39 '' the devices according to the invention can be designed as a T-piece, as in 1a shown.

Because the carrier gas flow is known and constant across the gas flow regulator 23 is regulated, the proportions of ionic and elemental mercury can be calculated and specified very precisely. Through this gas flow control, which in the generator 2 Thus, any ratio between 0 and 100% of elemental mercury in the purified gas stream can be obtained. This is present as the test gas of a consumer device 11 fed.

In 3 an evaporator chamber converter compact unit according to the invention is shown. The converter 31 and the converter material contained in it are here together with the evaporator chamber 35 included in a unit. It is this case, a housing 44 which withstands the temperatures which arise when carrying out the process according to the invention. By integrating both devices to be heated (converter 31 and evaporator chamber 35 ) can be used here on a common heater (not shown). It should be noted that the catalyst may come to a temperature in the range of 100 ° C to 500 ° C during the conversion reaction; the devices according to the invention work with gunmetal as catalyst preferably in the range from 120 ° C to 250 ° C. This is advantageous in terms of space and in terms of high energy consumption, a device that reduces energy consumption compared to devices of the prior art.

The evaporator chamber 35 is at the inlet nozzle 43 charged with the mercury chloride solution to be evaporated; Inert gas or air passes through the opening 42 in the evaporator chamber 35 admitted. From the evaporator chamber 35 Coming now enters the resulting gas-vapor mixture in the evaporator outlet 38 one that branches to a substream T1 in a converter 31 to transfer and the other partial flow T2 via the evaporator outlet 38 ' to dismiss from the case. Not shown here is the restriction device, which is quite in the emerging from the housing line 39 ' can be arranged.

The converted gas stream passes over the line 39 out of the case and merges with the out of line 39 ' coming second partial flow at the junction 39 '' from where the test gas obtained with the desired composition is transferred to a consumer device, not shown figuratively.

The structurally clever arrangement, in 3 shown, advantageously avoids losses due to adsorption and condensation.

Furthermore, the housing 44 be provided with a discharge opening to swiftly and conveniently be able to replace either the catalyst or the entire converter can. Maintenance work is therefore manageable with little time.

in principle are suitable as converter materials for the invention Process which, as stated with the inventive Devices is performed, metals or a metal alloy from the group copper, zinc, tin, lead. Especially of gunmetal CuSn7ZnPb, (Material designation RG7 material number 2.1090) it was shown that he in the form of a bed or as a sintered material with a large surface, z. In the form of a disk, has a considerable capacity and service life. Therefore is a gunmetal with a porous, gas-permeable Surface for the said process especially good, especially as packing, packing, wire mesh, Foil or as a sintered disc.

The Life does not depend on the dose of mercury from the hydrogen chloride dose. Hydrogen chloride will evaporate the Solutions for stabilization added and generally has about a thousand times the concentration of mercury. Because this converter material is relatively inexpensive and works well in porous structure is a regular one Replacement after given hydrogen chloride dose readily possible.

The The invention is not limited to one of the above-described embodiments limited, but in many ways modifiable. All from the claims, the description and the drawing features and advantages, including constructive details, spatial arrangements and Procedural steps, both for themselves also be essential to the invention in the most diverse combinations.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0923985 B1 [0005]

Claims (30)

Process for the preparation of a gas-vapor mixture containing ionic mercury (Hg, ion) and elemental mercury (Hg, el), comprising the steps of: • dividing a gas-vapor mixture stream containing ionic mercury (Hg, ion) after leaving one Evaporator ( 5 . 35 ) into a first partial flow (T1) and into a second partial flow (T2), • transfer of the first partial flow (T1) into a converter ( 21 . 31 ), Contacting the first substream (T1) with one in the converter ( 21 . 31 ) comprising the first substream (T1) containing elemental mercury (Hg, el) with the second substream (T2) containing ionic mercury (Hg, ion) downstream of the converter ( 21 . 31 ), Transferring the gas-vapor mixture containing ionic mercury (Hg, ion) and elemental mercury (Hg, el) into a consumer device ( 11 ). A method according to claim 1, characterized in that the first partial flow (T1) before and / or after the converter ( 21 . 31 ) is adjustable and / or regulated. Method according to claim 1 or 2, characterized in that the second partial flow (T2) of a restriction device ( 10 ) is supplied. Method according to one of claims 1 to 3, characterized in that the catalyst during the conversion reaction to a temperature in the range of 100 ° C to 500 ° C, preferably in the range of 120 ° C to 250 ° C, heated. Method according to one of claims 1 to 4, characterized in that the catalyst is a copper-containing Catalyst compound, in particular a gunmetal is. Apparatus for producing a gas-vapor mixture containing ionic mercury (Hg, ion) and elemental mercury (Hg, el), in particular for carrying out the method according to one of claims 1 to 5, with an evaporator ( 5 . 35 ), whose evaporator chamber with an evaporator outlet ( 8th . 38 ) with a first branch ( 8th'' . 38 '' ), by means of one of the evaporator ( 5 . 35 ) into the evaporator outlet line ( 8th . 38 ) transferred gas-steam stream into a first partial flow (T1) and into a second partial flow (T2) can be divided, • with a converter ( 21 . 31 ), suitable for the representation of elemental mercury (Hg, el), which is equipped with a converter outlet line ( 9 . 39 ), wherein the converter ( 21 . 31 ) so with the branching ( 8th'' . 38 '' ) of the evaporator outlet line ( 8th . 38 ) is in flow communication that the first partial flow (T1) of the gas-steam flow into the converter ( 21 . 31 ) is convertible, and • wherein the converter outlet ( 9 . 39 ) in a second branch ( 9 '' . 39 '' ), which corresponds to that of the converter ( 2 . 31 ) into the converter outlet line ( 9 . 39 ) transferred first partial stream (T1) and the second partial stream (T2) of the gas-vapor stream to the gas-vapor mixture. Apparatus according to claim 6, characterized in that the evaporator ( 5 ) Component of a dosing evaporator system ( 1 ). Apparatus according to claim 7, characterized in that the dosing evaporator system ( 1 ) at least one metering pump ( 3 ), a gas flow regulator ( 4 ) and the evaporator ( 5 ) having. Apparatus according to claim 7 or 8, characterized in that the dosing evaporator system ( 1 ) is capable of providing a gas-vapor mixture having a temperature in the range of 160 ° C to 200 ° C, preferably 180 ° C. Device according to one of claims 6 to 9, characterized in that the converter ( 21 . 31 ) is heated. Device according to claim 10, characterized in that the converter ( 21 . 31 ) has a metal or a metal alloy from the group copper, zinc, tin, lead as a catalyst. Device according to claim 11, characterized in that that the metal alloy is a gunmetal. Device according to claim 12, characterized in that that the gunmetal a porous, gas-permeable surface having. Device according to one of claims 11 to 13, characterized in that the catalyst as a bed, packing, wire mesh, foil or sintered material in the converter ( 21 . 31 ) is present. Device according to one of claims 1 to 14, characterized in that the converter ( 21 . 31 ) Component of a generator ( 2 ). Device according to claim 15, characterized in that the generator ( 2 ) at least one gas cooler ( 22 ), a gas flow regulator ( 23 ) and the converter ( 21 . 31 ) having. Device according to claim 15 or 16, characterized in that the converter ( 21 ), the gas cooler ( 22 ) and the gas flow regulator ( 23 ) are connected in series. Device according to one of claims 15 to 17, characterized in that the converter ( 21 ), the gas cooler ( 22 ) and the gas flow regulator ( 23 ) via the converter outlet line ( 9 . 39 ) are in fluid communication. Device according to one of claims 15 to 18, characterized in that the converter ( 21 . 31 ) has an inlet opening into which the first branch ( 8th'' . 38 '' ) opens. Device according to one of claims 15 to 19, characterized in that the gas flow regulator ( 23 ) has an outlet opening, which via the converter outlet ( 9 . 39 ) in the second branch ( 9 '' . 39 '' ) opens. Device according to one of the preceding claims, characterized in that in the evaporator outlet line ( 8th ) downstream of a restriction device ( 10 ) is provided, suitable for throttling the second partial flow (T2). Device according to claim 21, characterized in that the restriction device ( 10 ) between the first branch ( 8th'' . 38 '' ) and the second branch ( 9 '' . 39 '' ) is arranged. Device according to claim 21 or 22, characterized in that the restriction device ( 10 ) is a heated capillary. Device according to claim 23, characterized in that the capillary ( 10 ) has a greater flow resistance than the converter ( 21 . 31 ) and / or the generator ( 2 ). Device according to one of the preceding claims, characterized in that the gas-vapor mixture of at least one consumer device ( 11 ) can be fed. Device according to one of the preceding claims, characterized in that the evaporator ( 5 . 35 ) a gas-vapor mixture with a proportion of ionic mercury in the range of 95% to 100%, preferably in the range of 98% to 100%, for feeding into the evaporator outlet ( 8th . 38 ). Device according to one of the preceding claims, characterized in that the first and / or the second branch ( 8th'' . 38 ''; 9 '' . 39 '' ) are formed by tees. Device according to one of the preceding claims, characterized in that the evaporator ( 35 ) and the converter ( 31 ) in a common housing ( 44 ) are arranged. Device according to claim 28, characterized in that the housing ( 44 ) at least one removal opening for replacement of the converter ( 31 ) and / or the catalyst. Use of a gunmetal catalyst in one Apparatus for producing a gas-vapor mixture containing ionic and elemental mercury according to a of claims 6 to 29.