DE102022209827A1 - Thermal treatment of mineral material, especially clays, for the cement industry, especially for the production of artificial pozzolans - Google Patents

Abstract

The present invention relates to a method for producing thermally treated clays in a calciner 10, wherein the pollutants released when the clay is heated are thermally converted in the calciner 10.

Description

The invention relates to a method for the thermal treatment of mineral material, in particular clays, and a system for this, the material properties being used at the same time to reduce the air pollutants produced during production.

Clays and clay-like substances are now often used, for example, to produce artificial pozzolans, which are then used in cement production. One reason for this is that when producing cement clinker, for example from limestone, CO ₂ escapes from the raw material. In order to reduce CO ₂ emissions, switching to a different starting product, currently for example clay, is an important step in order to avoid emissions that are harmful to the climate.

A disadvantage of clays is that they contain a number of substances with different compositions. A substance that often comes out of the clay during the thermal treatment of clay when the material is preheated is ammonia. Since ammonia should not (and must not) be released into the atmosphere, exhaust gas treatment is carried out downstream, which treats the exhaust gas that comes from the preheater and removes pollutants such as ammonia and/or nitrogen oxides from the exhaust gas. Such exhaust gas purification is now state of the art and can usually be found in practically every industrial plant that processes materials at higher temperatures.

Another pollutant that often escapes when clays are heated are hydrocarbons and hydrocarbon-containing compounds, summarized here and below for simplicity (and neglecting other heteroatoms) under C _x H _y , which also have to be removed from the exhaust gas.

From the DE 10 2011 014 498 A1 a process for producing a clinker substitute is known.

From the US 9,458,059 B2 A manufacturing process for synthetic pozzolans is known.

The object of the invention is to provide a process which enables the thermal treatment of mineral material, in particular clays, to be as energy-saving as possible and therefore environmentally friendly.

This task is solved by the method with the features specified in claim 1. Advantageous further developments result from the subclaims, the following description and the drawings.

The method according to the invention is used to produce thermally treated mineral material, in particular clays, for example and in particular to produce artificial pozzolans for use in the cement industry. The production takes place in a calciner. When clays are heated, pollutants are released that should not be released into the environment. These are, for example and in particular, ammonia NH ₃ and hydrocarbons and compounds containing hydrocarbons. These pollutants are usually converted in an energy-intensive manner in an exhaust gas treatment downstream of the manufacturing device and are thus removed. However, this process is energy-intensive and therefore leads to further, avoidable CO ₂ emissions. Therefore, the pollutants released when the clay is heated are thermally converted in the calciner. The calciner is at the right temperature for the decomposition of pollutants. There is also an additional, very positive effect. Ammonia usually comes out of the clay. Nitrogen oxides are formed during the combustion required to generate the temperature in the calciner. The nitrogen oxides from the combustion process synproportionate with the ammonia from the clay to form nitrogen and water. This creates a double benefit and the usual, energy-intensive downstream exhaust gas treatment can even be dispensed with.

In a further embodiment of the invention, at least part of the mineral material, in particular the clay, is introduced directly into the calciner without preheating. This initially seems absurd because, in contrast to the state of the art, energy recovery in the preheater is dispensed with. However, if you look at the entire process, including exhaust gas purification, it is surprising that foregoing preheating is more than compensated for by the energy saved in exhaust gas purification. And if downstream exhaust gas purification is still carried out, the reduction rates required there are significantly lower. In addition, the exhaust gas enters at a higher temperature, so that the energy requirement also decreases.

Without preheating in the sense of the invention is meant a heating in which heating takes place close to the treatment temperature and this can be associated with a release of pollutants. However, clays in particular must be dried before use. For this purpose, the starting material is heated, but not too much a temperature window of 70 °C to 120 °C (the maximum temperature varies depending on the drying method and the raw material used). However, the emissions of pollutants according to the invention do not yet occur in this temperature window, so that drying alone is not critical with regard to these emissions. Without preheating therefore preferably means in the sense of the invention with a temperature of at most 120 ° C.

In a further embodiment of the invention, at least part of the mineral material, in particular the clay, is introduced into a part of the preheater adjacent to the calciner and preheated in the preheater and transferred from there to the calciner. For example, the preheater is a cascade of two to six co-current heat exchangers with cyclone separators. In this case, the mineral material, in particular the clay, is fed into the warmest co-current heat exchanger adjacent to the calciner. This embodiment is preferred if the calciner is operated at a comparatively high temperature, for example and in particular between 800 ° C and 1200 ° C. In this case, the temperature in this first part of the preheater is so high that the mineral material, in particular the clay, can be reliably decomposed when heated. This allows a balance to be achieved between heat recovery and effective pollutant minimization.

In a further embodiment, a second mineral raw material is introduced into the preheater, with a mineral raw material being selected as the second mineral raw material which emits no or only very small amounts of pollutants during heating. Typical examples are limestone or sand, which are used together with artificial pozzolans in mixtures in the cement industry. This means that heat recovery can be achieved with the less critical educts and at the same time complex exhaust gas cleaning can be prevented.

In a further embodiment of the invention, at least part of the mineral material, in particular the clay, is introduced into a preheater and preheated in the preheater and from there transferred to the calciner. Therefore, the pollutants already emerge from the mineral material, in particular the clay, in the preheater and are therefore in the gas stream coming from the preheater. Therefore, the gas coming from the preheater is at least partially fed into the calciner. For this purpose, the gas stream coming from the preheater can be fed, for example, to a combustion chamber that is connected to the calciner. As a result, the pollutants also reach the calciner as with the direct introduction of the mineral material, in particular the clay, and have the same positive effect, in particular on the nitrogen oxides generated during the combustion required to generate the temperature.

In a further embodiment of the invention, the gas coming from the preheater is fed into the calciner via a material cooler. A combustion chamber can also be arranged between the material cooler and the calciner. As a result, the heat discharged by the product from the calciner is fed back into the process.

In a further embodiment of the invention, the gas coming from the preheater is fed to a dedusting device, which is designed, for example, as a fabric filter, ceramic filter or electrostatic precipitator, before being fed into a combustion chamber. As a result, the dust content in the gas coming from the preheater is separated and can be fed back into the system at a suitable location, for example the calciner or the preheater. This prevents the dust content in the combustion chamber from heating to an undesirably high temperature and thus being thermally deactivated.

In a further embodiment of the invention, at least one reactant is supplied to the gas coming from the preheater before the gas is supplied to the calciner. The reactant can be used, for example, to convert sulfur compounds, in particular to convert them into sulfate. Sulfate is a desired additive in the cement industry, meaning that sulfur impurities can be used profitably in this way.

In a further embodiment of the invention, the calciner has a temperature between 600 ° C and 1400 ° C, preferably between 600 ° C and 1200 ° C, more preferably between 750 ° C and 1050 ° C, particularly preferably between 800 ° C and 1000 °C operated.

In a further embodiment of the invention, a fuel is supplied to the calciner. The fuel is selected from the group including pulverized coal, natural gas, biogas, hydrogen, ammonia and synthesis gas. These fuels are highly energetic and allow for good firing.

In a further embodiment of the invention, sulfur-containing compounds from the mineral material, in particular the clay, are oxidized to sulfate in the calciner. Sulfates are common additives in cement, so that the sulfur can be bound to create value and provide added value for the finished product. At the same time, environmentally harmful emissions are avoided.

In a further aspect, the invention relates to a device for the thermal treatment of mineral material, in particular clays. The device has a calciner. The device also has an educt feed. It is important that the educt feed introduces mineral material, especially clay, directly into the calciner without preheating. This means that the mineral material, especially the clay, is first heated in the calciner. This in turn causes the pollutants, in particular ammonia, hydrocarbons and hydrocarbon compounds, to be released precisely in the calciner at the high temperature of the calciner. Hydrocarbons and hydrocarbon-containing compounds are burned directly, and ammonia is converted into nitrogen and water with the nitrogen oxides produced at these high temperatures. In this way, the pollutants are converted directly in the calciner. To do this, there is no need to preheat the educt and thus recover energy from the exhaust gas. This seems illogical as it worsens efficiency. However, it has been found that this makes it possible to avoid the need for complex exhaust gas purification, which also requires a lot of energy.

In a further embodiment of the invention, the calciner is connected directly to an exhaust gas treatment or a fume hood without an intermediate preheater. In this embodiment, the material stream is completely brought into the calciner without preheating. In addition, if additional treatment is necessary, the exhaust gas flow can already be brought to the temperature of the gas outlet of the calciner, which makes the usually necessary reheating of the exhaust gas unnecessary.

In a further aspect, the invention relates to a device for the thermal treatment of mineral material, in particular clays, the device having a calciner and a preheater. This corresponds to the conventional structure. According to the invention, a gas flow divider is arranged in the gas flow leaving the preheater. The gas flow divider serves to divide the gas flow into a recirculation gas flow and an exhaust air flow. The gas flow divider is connected to a return line. The return line serves to receive the recirculation gas stream. The return line is connected to the calciner or a combustion chamber or a material cooler. This uses two effects. On the one hand, in the preheater, as before, the energy can at least partially be fed back into the process by preheating the material to be thermally treated. On the other hand, the pollutants are at least partially transferred to the calciner via the gas divider and can be converted there. Since complete recirculation would lead to an enrichment of, for example, the CO ₂ originating from the firing, part of the gas stream must also be released into the environment as an exhaust air stream.

In a further embodiment of the invention, the return line has a dedusting device.

In a further embodiment of the invention, the dedusting device is connected to a dust return line. The dust return line has two ends. One end is connected to the dedusting device, the other end is connected to the calciner or preheater. This also includes an indirect connection, for example the connection between the calciner and the preheater or a material feed device to the preheater or calciner. This allows the dust to be fed into the product without overheating and therefore without deactivation, for example in the combustion chamber.

In a further embodiment of the invention, the educt feed has an educt flow division. The educt flow division is connected to a first partial duct current line and a second partial duct current line. The first partial duct current line is connected to the calciner and the second partial duct current line is connected to the preheater. As a result, a mixed form of the two aforementioned devices can be used to carry out the method according to the invention. The first partial duct stream is then fed directly to the calciner, which results in optimal pollutant minimization. At the same time, part of the thermal energy can be fed back into the process via the second partial duct stream and the preheater. In addition, the device has a second educt feed, wherein the second educt feed is designed to feed a second mineral raw material. The second educt feed is connected to the preheater and a second mineral raw material can be fed to the preheater via the second educt feed and the return of the thermal energy from the exhaust gas of the preheater can be further improved. The second mineral raw material is, for example, limestone or sand, which releases little or no pollutants when preheated and can therefore be used to recover thermal energy in the preheater without any problems.

In a further embodiment of the invention, the device has at least one first temperature sensor. The temperature sensor is arranged in the calciner or between the calciner and preheater. The device further has at least one auxiliary combustion device. The auxiliary combustion device serves in particular to compensate for temperature fluctuations and is therefore usually operated with a fuel that is easy to meter and has a constant calorific value, for example gas or pulverized coal. The auxiliary combustion device is arranged on the combustion chamber, between the combustion chamber and the calciner or in the calciner. The device has a first control device. The first control device is connected to the first temperature sensor and the auxiliary combustion device. The first control device is designed to control the auxiliary combustion device depending on the temperature detected by the first temperature sensor.

In a further embodiment of the invention, the device has at least a first NO _x analyzer. For example and in particular, the NO _x analyzer detects the NO _x concentration using infrared spectroscopy in an extractive measurement. The NO _x analyzer is arranged in the calciner or between the calciner and preheater or in the preheater or after the preheater. The device has at least one educt flow divider and/or at least one second educt feed and/or a gas flow divider. The device has a first control device or a second control device. The first control device or the second control device is connected to the first NO _x analyzer and/or at least a first temperature sensor and the educt flow divider and/or the gas flow divider. The first control device or the second control device is designed to control the educt flow division and/or the gas flow divider depending on the NO _x concentration detected by the first NO _x analyzer, taking into account the prevailing temperatures. This makes it possible to easily adapt to a fluctuating composition of the starting material and thus to a fluctuating release of pollutants in the process.

In a further embodiment of the invention, the device has at least a first organic analyzer. An organic analyzer can be, for example, a flame ionization detector for detecting the concentration of hydrocarbon and hydrocarbon-containing compounds. The organic analyzer is arranged in the calciner or between the calciner and preheater or in the preheater or after the preheater. The device has at least one educt flow divider and/or at least one second educt feed and/or a gas flow divider. The device has a first control device or a second control device. The first control device or the second control device is connected to the first organic analyzer and/or at least a first temperature sensor and the educt flow divider and/or the gas flow divider. The first control device or the second control device is designed to control the educt flow division and/or the gas flow divider depending on the organic concentration detected by the first organic analyzer, taking into account the prevailing temperatures. This makes it possible to easily adapt to a fluctuating composition of the starting material and thus to a fluctuating release of pollutants in the process.

In a further embodiment of the invention, the device has at least a first NH ₃ analyzer. The NH ₃ analyzer is arranged in the calciner or between the calciner and preheater or in the preheater or after the preheater. The device has at least one educt flow divider and/or a gas flow divider. The device has a first control device or a second control device. The first control device or the second control device is connected to the first NH ₃ analyzer and/or the temperature sensor and the educt flow divider and/or the gas flow divider. The first control device or the second control device is designed to control the educt flow division and/or the gas flow divider depending on the NH ₃ concentration detected by the first NH ₃ analyzer and/or the temperature level detected by the temperature sensor.

The aforementioned devices are particularly preferably designed to carry out the method according to the invention or the method according to the invention can particularly preferably be carried out on one of the aforementioned devices.

• 1 erstes Ausführungsbeispiel
• 2 zweites Ausführungsbeispiel
• 3 drittes Ausführungsbeispiel
• 4 viertes Ausführungsbeispiel

The method according to the invention is explained in more detail below using exemplary embodiments shown in the drawings.

• 1 first embodiment
• 2 second embodiment
• 3 third embodiment
• 4 fourth embodiment

In 1 the direct educt feed 30 into the calciner 10 is shown. The device does not have a preheater. The gas leaving the calciner 10 is released directly as exhaust air; the educt is not preheated and heat recovered in the preheater. The product leaving the calciner 10 is cooled in a material cooler 20 and leaves the device via the product stream 40. Gas, for example air, is fed to the material cooler 20 via the gas supply 50 and from there preheated to the calciner 10. The calciner 10 has a combustion device which is either arranged in the calciner 10 or upstream of the calciner 10. The nitrogen oxides produced during combustion there are reacted with the ammonia from the clay, so that no or only tolerable emissions are produced. Likewise, hydrocarbons and hydrocarbon-containing compounds that come from the clay are reliably burned to a sufficient extent. The lack of heat recovery in a preheater is compensated for by the fact that no additional energy has to be used for exhaust gas cleaning.

2 shows a second, alternative embodiment. Here, as usual, the educt is fed 30 to the preheater 70 by transferring the heat from the gas coming from the calciner 10 to the educt. However, this leads to the release of ammonia and/or hydrocarbons and hydrocarbon-containing compounds. In order to reduce this, the gas flow is passed through a gas flow divider 80 after the preheater 70. A partial stream is released as exhaust air 80, a further partial stream is combined with the gas supply 50 and fed to the material cooler and thus fed to the calciner 10 via the material cooler 20. In the calciner 10, the nitrogen oxides generated by combustion are then converted again by ammonia released from the clay and hydrocarbons and hydrocarbon-containing compounds are also burned. The preheated material is moved from the preheater 70 into the calciner 10 and, after the thermal treatment in the calciner 10, into the material cooler 20 and leaves the device as a product stream 40.

In the 3 The third embodiment shown represents a mixed form of the first embodiment and the second embodiment. The educt feed 30 takes place to an educt stream division 90. Here the educt stream is divided and a first partial duct flow line 31 leads an unpreheated partial flow of the educt directly into the calciner 10 and a second partial duct flow line 32 leads a partial stream of the educt into the preheater 70. As a result, a part is only heated in the calciner 10, so that the substances released here, in particular ammonia as well as hydrocarbons and hydrocarbon-containing compounds, can be converted directly in the calciner 10. The other partial stream can recover part of the heat of the gas stream from the calciner 10 in the preheater 70. As a result, the unwanted substances also escape during heating in the preheater 70. Some of these are returned to the calciner by the division in the gas flow divider 80 and can be rendered harmless there. This third embodiment has the advantage that an adjustment can be made using two setting options (educt flow divider 90 and gas flow divider 80). This can be useful, for example, to compensate for fluctuating emissions caused by differences in sound. The preheated material is fed from the preheater 70 into the calciner 10 and combined there with the first partial duct stream. After the thermal treatment in the calciner 10, the material is brought into the material cooler 20 and leaves the device as a product stream 40.

4 shows a fourth embodiment, which differs from the third embodiment in particular in that this fourth embodiment has a control device 100 which is connected to three temperature sensors 110, a temperature sensor 110 in the calciner 10, a temperature sensor between the calciner 10 and preheater 70 and a another temperature sensor 110 is arranged in the calciner. Of course, additional temperature sensors 110 can also be present. In addition, the device has a NO _x analyzer 120, which detects the NO _x content in the exhaust gas of the preheater 70, and an NH ₃ analyzer 122, which corresponds to the NH ₃ content in the exhaust gas of the preheater 70. The control device 100 can in particular Depending on the NO _x concentration detected by the NO _x analyzer 120 and the NH ₃ concentration detected by the NH ₃ analyzer 122, control the educt flow division 90 and/or the gas flow divider 80. This allows, for example, more educt to be introduced directly into the calciner 10 when the NO _x concentration increases or more educt to be introduced into the preheater 70 in order to recover more energy at low NO _x concentrations. Likewise, at high NO _x concentrations, the proportion of recirculation in the gas flow divider can be increased.

In addition, the fourth embodiment shows a separate combustion chamber 130 in which, for example and in particular, substitute fuels, for example biomass, can be burned. In this case, the calciner 10 preferably has an auxiliary combustion device (not shown here), which is preferably also controlled via the control device 100. The temperature sensors 110 can be used to determine the temperature resulting from fluctuations in the calorific value of the substitute fuel Fluctuations are recorded and compensated accordingly via the auxiliary combustion device.

Reference symbols

10

Calciner

20

Material cooler

30

educt feed

31

first partial duct power line

32

first partial duct power line

40

Product stream

50

Gas supply

60

Exhaust air

70

Preheater

80

Gas flow divider

90

Educt stream division

100

Control device

110

Temperature sensor

120

NO _x analyzer

122

NH ₃ analyzer

130

combustion chamber

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011014498 A1 [0005]
• US 9458059 B2 [0006]

Claims (21)

Method for producing thermally treated mineral material, in particular clay, in a calciner (10), wherein the pollutants released when the mineral material, in particular the clay, is heated are thermally converted in the calciner (10). Procedure according to Claim 1 , characterized in that at least part of the mineral material, in particular the clay, is introduced directly into the calciner (10) without preheating. Method according to one of the preceding claims, characterized in that at least a second mineral raw material is selected. Procedure according to Claim 3 , characterized in that the at least one second mineral raw material is selected from the group comprising limestone or sand. Method according to one of the preceding claims, characterized in that at least part of the mineral material, in particular the clay, is introduced into a preheater (70) and preheated in the preheater (70) and from there transferred to the calciner (10), whereby the Gas coming from the preheater (70) is at least partially fed into the calciner (10). Procedure according to Claim 5 , characterized in that the gas coming from the preheater (70) is fed into the calciner (10) via a material cooler (20). Procedure according to one of the Claims 5 until 6 , characterized in that at least one reactant is supplied to the gas coming from the preheater (70) before the gas is supplied to the calciner (10). Method according to one of the preceding claims, characterized in that the calciner (10) is operated at a temperature between 600 °C and 1400 °C, preferably between 750 °C and 1050 °C, particularly preferably between 800 °C and 1000 °C . Method according to one of the preceding claims, characterized in that the calciner (10) is supplied with a fuel, the fuel being selected from the group comprising coal dust and other solid fuels, natural gas, biogas, hydrogen, ammonia and synthesis gas as well as liquid fuels such as oil . Method according to one of the preceding claims, characterized in that sulfur-containing compounds from the mineral material, in particular the clay, are oxidized to sulfate in the calciner (10). Device for the thermal treatment of mineral material, in particular clays, the device having a calciner (10), the device having an educt feed (30), characterized in that the educt feed (30) feeds mineral material, in particular clay, directly without preheating into the calciner (10). Device according to Claim 11 , characterized in that the calciner (10) is connected directly to an exhaust gas treatment or a fume hood without an intermediate preheater (70). Device for the thermal treatment of mineral material, in particular clays, the device having a calciner (10) and a preheater (70), characterized in that a gas flow divider (80) is arranged in the gas flow leaving the preheater (70), the gas flow divider (80) is connected to a return line, the return line being connected to the calciner (10), a combustion chamber (130) or a material cooler (20). Device according to Claim 13 , characterized in that the return line has a dedusting device. Device according to Claim 13 , characterized in that the dedusting device is connected to a dust return line, the dust return line being connected to the calciner (10) or the preheater (70) on the side opposite the dedusting device. Device according to Claim 11 in combination with one of the Claims 13 until 15 , characterized in that the educt feed (30) has an educt flow division (90), the educt flow division (90) being connected to a first partial duct flow line (31) and a second partial duct flow line (32), the first partial duct flow line (31) being connected to the calciner (10) and the second partial duct current line (32) is connected to the preheater (70). Device according to one of the Claims 11 until 16 , characterized in that the device has a second educt feed, wherein the second duct feed is connected to the preheater. Device according to one of the Claims 11 until 17 , characterized in that the device has at least one first temperature sensor (110), the temperature sensor (110) being arranged in the calciner (10) or between the calciner (10) and preheater (70), the device having at least one auxiliary combustion device, wherein the auxiliary combustion device is arranged on the combustion chamber (130), between the combustion chamber (130) and the calciner (10) or in the calciner (10), the device having a first control device (100), the first control device (100) being connected to the first Temperature sensor (110) and the auxiliary combustion device is connected, wherein the first control device is designed to control the auxiliary combustion device depending on the temperature detected by the first temperature sensor (110). Device according to one of the Claims 11 until 17 , characterized in that the device has at least a first NO _x analyzer (120), the NO _x analyzer (120) in the calciner (10) or between the calciner (10) and preheater (70) or in the preheater (70) or is arranged after the preheater (70), the device having at least one educt flow divider (90) and/or a gas flow divider (80), the device having a first control device (100) or a second control device (100), the first Control device (100) or the second control device (100) is connected to the first NO _x analyzer (120) and/or the temperature sensor (110) and the educt flow divider (90) and/or the gas flow divider (80), wherein the first control device or the second control device (100) for controlling the educt flow division (90) and/or the gas flow divider (80) depending on the NO _x concentration detected by the first NO _x analyzer (120) and/or that detected by the temperature sensor (110). Temperature levels are formed. Device according to one of the Claims 11 until 19 , characterized in that the device has at least a first organic analyzer, the organic analyzer being arranged in the calciner (10) or between the calciner (10) and the preheater (70) or in the preheater (70) or after the preheater (70). is, wherein the device has at least one educt flow divider (90) and / or a gas flow divider (80), wherein the device has a first control device (100) or a second control device (100), wherein the first control device (100) or the second control device (100) is connected to the first organic analyzer and / or the temperature sensor (110) and the educt flow divider (90) and / or the gas flow divider (80), wherein the first control device (100) or the second control device (100) for control the educt flow divider (90) and/or the gas flow divider (80) is formed depending on the organic concentration detected by the first organic analyzer and/or the temperature level detected by the temperature sensor (110). Device according to one of the Claims 11 until 20 , characterized in that the device has at least a first NH ₃ analyzer, the NH ₃ analyzer in the calciner (10) or between the calciner (10) and the preheater (70) or in the preheater (70) or after the preheater (70 ) is arranged, wherein the device has at least one educt flow divider (90) and / or a gas flow divider (80), the device having a first control device (100) or a second control device (100), wherein the first control device (100) or the second control device (100) is connected to the first NH ₃ analyzer and/or the temperature sensor (110) and the educt flow divider (90) and/or the gas flow divider (80), wherein the first control device (100) or the second control device (100 ) is designed to control the educt flow division (90) and/or the gas flow divider (80) depending on the NH ₃ concentration detected by the first NH ₃ analyzer and/or the temperature level detected by the temperature sensor (110).

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