CH718435A2 - Device and method for producing cement clinker. - Google Patents

Abstract

Device and method for the production of cement clinker with the steps: burning raw material into cement clinker in a kiln (2), preheating the raw material with flue gases from the kiln (2) in a preheater (3), dust removal from the flue gases exiting from the preheater (3). and denitrification of the dedusted flue gases in a denitrification stage (5), in particular in an SCR system, the flue gases exiting the preheater (3) having a temperature of more than 260 °C, preferably from 300 °C to 400 °C, in particular essentially 350°C, dedusted in a hot gas filter (6) and passed from the hot gas filter (6) to the denitrification stage (5) at essentially the same temperature.

Description

The invention relates to a method for producing cement clinker with the following steps: burning raw material into cement clinker in a kiln, preheating the raw material with flue gases from the kiln in a preheater, dedusting the flue gases exiting the preheater and denitrifying the dust-free flue gases in a Denitrification stage, especially in an SCR system.

The invention also relates to a device for producing cement clinker, comprising: a kiln for burning raw material into cement clinker, a preheater, in particular with a cyclone cascade, for preheating the raw material with flue gases from the kiln, a dust filter for removing dust from the preheater escaped flue gases, a denitrification stage, in particular an SCR system, for denitrification of the dust-free flue gases.

[0003] Such a method for producing cement clinker is described in EP 3 149 422 B1. As usual, the flue gases flow through the preheating tower in countercurrent to the raw materials, so that the raw materials can be preheated with the heat of the flue gases before the rotary kiln. After leaving the preheating tower, the flue gases are fed into a raw mill, which is used to grind and dry fresh raw material. The flue gases, which leave the preheating tower at a temperature of 280 to 450°C, are used to dry the raw materials in the raw mill. After flowing through the raw mill, the flue gases are dedusted with a bag filter or electrostatic precipitator. The flue gases are then fed into an SCR (Selective Catalytic Reduction) system to convert the nitrogen oxides (NOX) in the flue gases into harmless compounds. Finally, the cleaned flue gases are discharged through the chimney. A recuperator is arranged in front of the SCR system, with which heat is transferred from the cleaned flue gases after denitrification to the flue gases to be cleaned before denitrification, whereby the flue gases to be cleaned are heated to the operating temperature of the denitrification catalyst. In order to compensate for the heat losses of the recuperator, a heat transfer system with two heat exchangers is provided, which enables heat transfer from the hot flue gases in front of the raw mill to the flue gases in front of the recuperator. It was also already known from earlier EP 2 545 337 B1 to use the heat produced in the furnace during the combustion process for the heat displacement system of the SCR system. In this prior art, a cyclone was used in the exhaust air flow to reduce the dust content of the flue gases before the heat exchanger for the transfer of furnace waste heat to the heat exchange medium. In EP 3 149 422 B1 it was recognized that dedusting with the cyclone was disadvantageous, since the dust content could not be reduced sufficiently to prevent disadvantageous dust deposits. For this reason, EP 3 149 422 B1 proposed placing a hot gas filter in front of the first heat exchanger of the heat transfer system. Such hot gas filters have ceramic or metal filter elements, which enable dust to be separated on the filter material at temperatures of more than 260°C. Thus, it is basically already known from EP 3 149 422 B1 to integrate a hot gas filter into the cement clinker plant, but only with the aim of reducing the dust content upstream of the heat transfer system for the SCR plant to such an extent that compact heat exchangers could be used. Although the cement clinker plant of EP 3 149 422 B1 has proven very effective, it is disadvantageously associated with a high outlay in terms of equipment.

In contrast, the object of the present invention is to alleviate or eliminate at least individual disadvantages of the prior art. The aim of the invention is preferably to improve the energy balance of the catalytic denitrification of flue gases from cement clinker production with as little equipment as possible.

[0005] This object is achieved by a method according to claim 1 and a device according to claim 4. Preferred embodiments are given in the dependent claims.

In the method according to the invention, the flue gases exiting the preheater are heated at a temperature of more than 260° C., preferably from 260° C. to 500° C., in particular from 300° C. to 400° C., for example essentially 350° C. dedusted in a hot gas filter and passed at substantially the same temperature from the hot gas filter to the denitrification stage.

In the device according to the invention, a hot gas filter is provided as the dust filter, which is connected directly to the denitrification stage, so that the flue gases exiting the preheater are at a temperature of more than 260° C., preferably from 260° C. to 500° C. in particular essentially 350°C, in which hot gas filters can be dedusted and fed to the denitrification stage at essentially the same temperature.

The inventive method realizes a "low dust" denitrification, in which the flue gases are dedusted before denitrification. A hot gas filter is used for dedusting, which enables the flue gases to be filtered at a temperature of more than 260 °C. According to the invention, the flue gases are essentially not cooled between the dedusting in the hot gas filter and the denitrification. Thus, the hot gas filter is connected directly to the denitrification stage, i.e. without the interposition of plant components that cause a significant cooling of the flue gases, in particular without the interposition of the raw mill with which the raw materials are produced. The cooling of the flue gases between the hot gas filter and the denitrification stage is preferably less than 30°C, in particular less than 20°C, for example less than 10°C. The flue gases are therefore advantageously routed over the entire route from the outlet of the hot gas filter to the inlet of the SCR system, while essentially retaining their entire heat content. On the one hand, this results in the advantage that a heat displacement system can be dispensed with. Thus, the additional heat exchangers for the heat transfer system can be saved. It is also advantageous that the raw mill is not connected between the hot gas filter and the denitrification stage, but preferably after the denitrification stage (seen in the flow direction of the flue gases). This avoids the flue gases being loaded with dust from the raw materials, which in the prior art of EP 3 149 422 B1 had to be removed with a separate dust filter in front of the second heat exchanger of the heat displacement system. This dust filter between the raw mill and the SCR system can also be saved according to the invention. By reducing the number of system components, the risk of failures can also be reduced. As with "Low Dust" SCR systems, the denitrification catalyst of the denitrification stage can be dimensioned more compactly or smaller than with "High Dust" SCR systems. Since the denitrification catalyst is deactivated less frequently, the service life is increased.

The hot gas filter has at least one hot gas filter element, preferably at least one filter cartridge, which is in particular substantially vertical, with a hot gas filter material, in particular ceramic or metal, with which the flue gases are filtered so that the dust is separated on the hot gas filter element. The dust can be cleaned and discharged from the hot gas filter element. In an embodiment of the hot gas filter element made of ceramic, for example, silicon carbide can be provided.

In a preferred embodiment of the method, the step is also provided: supplying a reducing agent, in particular urea or ammonia, in the flue gases before denitrification of the flue gases. The reducing agent is preferably introduced into the flue gases immediately before the denitrification stage. Additionally or alternatively, the reducing agent can be supplied between the preheater and the hot gas filter.

The denitrification stage is preferably designed as an SCR system which has a denitrification catalyst so that the nitrogen oxides (NOx) in the flue gases can be reduced.

In a preferred embodiment of the method, the step is also provided: Regenerative thermal oxidation (RTO) of the flue gases after denitrification of the flue gases.

In direct operation in cement production, the organic substances contained in the flue gas are oxidized through the use of the RTO and the emissions in a chimney are thus greatly reduced.

The invention is explained below with reference to preferred embodiments in the drawings. Fig. 1 schematically shows a device according to the invention for the production of cement clinker, in which a hot gas filter is arranged between a preheater and an SCR system in such a way that the flue gases drawn off from the preheater are dedusted at a temperature of more than 260 °C and essentially without Cooling of the SCR system are supplied. Fig. 2 shows an alternative embodiment of the device according to Fig. 1.

Figure 1 shows a cement clinker plant, i.e. a device 1 for the production of cement clinker, which is part of a cement plant. The device 1 has a furnace 2, in particular a rotary kiln, in which raw material, in particular raw meal, is sintered into cement clinker. In addition, a preheater 3, in particular a preheating tower, preferably with a cyclone cascade with a plurality of cyclones connected in series (not shown), is provided. In the preheater 3, the raw material is preheated before it enters the furnace 2 with the help of flue gases from the furnace 2. At the upper end of the preheater 3, the flue gases are drawn off. A dust filter 4 reduces the dust content of the flue gases (“dust removal”). In addition, the device 1 has a denitrification stage 5, which is designed as an SCR system for the selective catalytic reduction of nitrogen compounds (“denitrification”).

In the embodiment shown, a hot gas filter 6 is provided as a dust filter 4 . The hot gas filter 6 has at least one filter element, preferably a plurality of filter elements, in particular filter candles, on which the dust from the flue gases is separated. The separated dust can be fed into the preheater or fed to a silo (see arrow 7). After leaving the preheater 3, the flue gases exiting the preheater 3 are first cooled to a temperature of, for example, essentially 350° C. (arrow 8) using a cooling device, for example a water cooling system, and then dedusted at this temperature in the hot gas filter 6. The hot gas filter 6 is connected directly to the denitrification stage 5, i.e. in particular without the interposition of a heat displacement system, a raw mill and a further dust filter. As a result, the dedusted flue gases are conducted at essentially the same temperature of essentially 350° C. from the outlet of the hot gas filter 6 to the inlet of the denitrification stage 5 (cf. arrow 9). For the SCR of the nitrogen compounds, a reducing agent is added to the flue gases before the denitrification stage 5. The reducing agent can be introduced into the flue gases immediately before the SCR system (see arrow 10). Additionally or alternatively, the reducing agent can be introduced into the preheater 3 (see arrow 11) or into the flue gas line between the preheater 3 and the hot gas filter 6 (see arrow 12).

In the embodiment shown, a bypass line 13 is also provided, which is branched off between the preheater 3 and the hot gas filter in order to be able to bypass the hot gas filter 6 and the denitrification stage 5 selectively. After denitrification, the flue gases can be fed to a raw mill (see arrow 14), with which the raw materials for cement clinker production are ground. Alternatively, the flue gases can be fed to a chimney after denitrification.

In the embodiment of FIG. 2, an RTO stage 15 is arranged after the denitrification stage 5, with which a regenerative thermal oxidation of the denitrified flue gases is carried out.

Claims (4)

1. Process for the production of cement clinker with the steps: burning raw material into cement clinker in a kiln (2), Preheating the raw material with flue gases from the furnace (2) in a preheater (3), Dedusting the flue gases exiting the preheater (3) and Denitrification of the dedusted flue gases in a denitrification stage (5), in particular in an SCR system, characterized in that the flue gases exiting the preheater (3) with a temperature of more than 260 °C, preferably 300 °C to 400 °C, in particular essentially 350 °C, dedusted in a hot gas filter (6) and with essentially the same temperature from the Hot gas filter (6) are routed to the denitrification stage (5). 2. The method according to claim 1, characterized by: Supplying a reducing agent, in particular urea or ammonia, to the flue gases before denitrification of the flue gases, preferably immediately before the denitrification stage (5). 3. The method according to claim 1 or 2, characterized by: Regenerative thermal oxidation (RTO) of the flue gases after denitrification of the flue gases. 4. Device for the production of cement clinker, comprising: a kiln (2) for burning raw material into cement clinker, a preheater (3), in particular with a cyclone cascade, for preheating the raw material with flue gases from the furnace (3), a dust filter (4) for removing dust from the flue gases exiting the preheater (3), a denitrification stage (5), in particular an SCR system, for denitrification of the dust-free flue gases, characterized in that A hot gas filter (6) is provided as the dust filter (4), which is connected directly to the denitrification stage (5).