EP0484955A2 - Method and device for the treatment of humid mixtures of gas and dust - Google Patents

Abstract

Process for the treatment, in particular, of coal dust mixtures in grinding drying plants. In order to prevent condensation of residual moisture in dust which may have been stored temporarily, heated inert gas being used for the transport of the coal dust or for the intermediate storage.

A device for heating inert gas contains a tube coil (7) which is provided in the longitudinal direction of the lining (6) of a smoke gas generator (2).

Description

The invention relates to a method and a device for the treatment of moist, explosive gas-dust mixtures, in particular coal dust mixtures in grinding drying plants.

In processes of this type, which are sufficiently known in blast furnace technology and coal-fired power plant technology, and which are largely described below by way of example on the basis of the treatment of moist raw coal to form air-coal dust mixtures, a flue gas flow has usually been used initially. Flue gas and especially hot process gas flow through the mills used in the grinding of moist raw coal as part of the mill drying process. Due to this flue gas flow, a large part of the moisture contained in the raw coal can be evaporated, the flue gas blown into the mill simultaneously serving as a transport medium for the coal dust mixture through the pipelines and the subsequent dust separators.

Since there are often different capacities in the grinding process in the mills and in the eventual combustion of the coal dust mixture, the coal dust is then discharged to the dust separator from the grinding and drying system and temporarily stored in silos or storage bunkers.

In order to prevent coal dust explosions, deflagrations or the like during transport of the coal dust mixture or in the phase of intermediate storage of the coal dust, spraying with cold inert gas is already used here, so that the formation of explosive mixtures is avoided.

Longer transport routes of the coal dust mixture also in the context of the flue gas flow and the supply of cold inert gas in subsequent phases such. B. the intermediate storage, however, lead to the fact that the temperature of the dust mixture or the dust in a silo can drop below the dew point temperature of the water vapor and thus condensation of the residual moisture contained in the dust mixture or dust occurs.

This condensation of even the residual moisture often leads to a lumping of the coal dust, which in turn is accompanied by difficulties in discharging the coal dust mixture by means of the gas flow. Deposits can form in the pipes in this way and, above all, blockages of injection nozzles occur, via which the coal dust mixture z. B. in the burners of blast furnaces.

Such a condensation into the cooler area can be determined, especially when coal dust is temporarily stored in storage bunkers, so that even a head heating, as is often carried out, hardly remedies this in the upper area of the storage bunker.

DE 35 45 828 A1 describes a process in an inert gas-operated grinding plant in which the inert gas is circulated. In the case of circulatory processes, there is a risk during a mill drying process that that evaporated regrind moisture accumulates more and more and the operating temperature finally comes to around the dew point temperature. If the temperature falls below the dew point, water would fail and form sludge together with the coal dust. According to this document, this is prevented by passing the gas through a cooler, in which the moisture is removed via a condensation process. When the system is at a standstill, however, there is a risk that the dust mixture which settles will reach the range of the dew point temperature and the associated disadvantages will occur.

DE 37 34 359 describes a coal grinding plant with an inert gas circuit. With this system, too, there is a risk that the coal dust will settle in the transport devices or bearings if the process is interrupted, and the range of the dew point temperature with the resulting disadvantages will result.

In the German magazine "Zement-Kalk-Gips" (35th year, No. 5, 1982, pp. 230 to 238), a coal grinding drying plant is described in a pressure-shock resistant design with pressure relief. Here a hot process gas is used to transport the coal. However, due to the pressure-shock resistant design, this document relates to a coal grinding plant with a non-inert operating mode.

Taking these problems into account, the object of the invention is therefore to create a method and an economical device of the type mentioned at the beginning, by means of which improvements in the subsequent fluid transport and the greatest possible freedom from maintenance of the systems used can be achieved in the case of explosion-critical gas-dust mixtures of materials .

This object is achieved according to the invention by using a preheated or heated inert gas to a temperature higher than the dew point temperature of the residual moisture of the dust mixture.

While it is known to use a hot process or system gas for drying and transporting a moist dust mixture, e.g. B. a flue gas, which is naturally above the dew point temperature of the damp dust mixture, an additional cold foreign inert gas, z. B. used from a storage container, which is only heated above the dew point temperature of the damp dust mixture, so as to ensure drying of the dust mixture and to avoid condensation of moisture. As a result, condensation of moisture can be avoided in the transport lines or in intermediate containers, even if the system for producing the hot process gas fails. By introducing the heated additional foreign inert gas, the safety of such a system is significantly increased.

This solution avoids the very serious problem of condensation of the residual moisture present in the coal dust and thus ultimately agglomeration of the dust particles. The heating is expediently carried out to about 30 ^° C. above the dew point temperature in order to reliably preclude the condensation. Nitrogen gas (N₂) or carbon dioxide (CO₂) can preferably be used as inert gases. In particular when spraying coal dust in storage bunkers, it is advantageous to use CO₂ gas for this, since this can also penetrate along the inner outer walls of the storage bunker due to its specific weight into the lower areas of the storage bunker and thus condensate water vapor there too prevented. An alternative or additional possibility for better fluidization of the coal dust can be achieved by means of gassing cushions or boxes or also mushroom-shaped nozzles for the inflow of inert gas in the area of the storage bunker outlet.

The measures of the process can be used in both externally inerted and self-inert grinding drying systems. Since hot-gas generators in the sense of smoke-gas generators are generally present in these mill-drying systems, the heating or heating of the inert gas can take place directly or directly coupled with these hot-gas generators.

As an alternative for inert gas heating, the installation of tubular fronds in the casing or lining of the burner chamber is an option. As further alternatives in terms of retrofitting the mill drying systems, the heating of the inert gas can also be carried out in a separate heat exchanger which is provided directly in the flue gas flow. Another possibility is the installation of tube fronds for the inert gas after the burner chamber, so to speak parallel to the flue gas duct.

The inert gas heated in this way can therefore at the appropriate points, z. B. the storage bunker inerting or the inertization for the coal dust transport to the storage bunkers etc.

With regard to emergency shutdowns of the mill drying system or the flue gas generator, in which heated inert gas is not available, the inert gas pipe system can be switched over to an air flow, so that scaling of the pipe system is prevented.

An essential core idea of the invention must therefore be seen in recognizing the interdependencies in the entire system of a mill drying system and in creating a seemingly simple measure to provide a convincing remedy for disruptive effects in the overall system.

Fig. 1

einen Längsschnitt durch ein erstes Ausführungsbeispiel eines Rauchgaserzeugers mit integrierter Inertgasleitung und

Fig. 2

einen vergleichbaren Schnitt durch ein zweites Ausführungsbeispiel eines Rauchgaserzeugers mit Gehäuseummantelung und nachfolgender Rauchgasableitung.

In the following, the invention will be explained by way of example using two schematic exemplary embodiments of a smoke gas generator. Show it:

Fig. 1

a longitudinal section through a first embodiment of a smoke gas generator with integrated inert gas line and

Fig. 2

a comparable section through a second embodiment of a flue gas generator with casing and subsequent flue gas discharge.

The schematic section according to FIG. 1 shows a flue gas generator 2, in which the interior designed as a burner chamber is fired via a burner 3. The burner chamber is surrounded by a refractory lining 6, in which the burner flame 5 is indicated schematically. In the example, a tubular frond 7 is provided in the longitudinal direction of the lining 6 in the left region of the thicker lining 6. This frond 7 is connected to an inlet line 8 and an outlet line 9 for the inert gas to be heated.

Cold inert gas is usually supplied via the inlet line 8 via corresponding valves, and an air supply, in particular for emergency situations, is also possible. The Outlet line 9 is connected to a corresponding distribution system for storage bunkers or the transport lines.

In the example according to FIG. 2 an alternative for an economical heating of the inert gas with a somewhat modified smoke gas generator 12 is shown. In the sectional view in the longitudinal direction of the smoke gas generator 12, the burner 3 and the lining 6 open to the right are shown with the same reference number. The flame 5 is indicated within the burner chamber.

The hot process gas flow 22 arises from the fact that the housing jacket 14 is provided at a short distance from the outer wall of the lining, so that flow channels are formed around the combustion chamber here. Process gas for heating is blown or sucked in via the inlet opening 15 by blowers or by the thermal differences, which flows in the front right area as process or hot gas flow 22 through the mill drying system.

As a first alternative, the example according to FIG. 2 shows the arrangement of a pipe frond 7 for the inert gas adjacent to the right-hand end of the brick lining 6, so that this pipe frond 7 still comes to rest in the area of the flame 5 of the burner 3. One can therefore speak of a parallel arrangement to the process gas duct 22.

Another alternative is shown in the right part of FIG. 2, where a heat exchanger 21 is installed directly in the process gas flow 22.

The initially cold inert gas is passed through the tube frond 7 or the heat exchanger 21. B. is heated to a temperature of 50 to 90 ^o C, but in any case above the dew point temperature of the gas-coal dust mixture.

In the aforementioned sense, the invention provides an excellent possibility of avoiding condensation of the residual moisture even after the coal dust has been discharged for intermediate storage or the like, which ultimately leads to a considerable reduction in the susceptibility to failure of the entire system or the mill drying system.

Claims (6)

Process for the treatment of moist, explosive gas-dust mixtures, in particular coal dust mixtures, in grinding drying systems for fluid transport and in the storage of dust resulting therefrom, using a flue gas, in particular a hot process gas, and an inert gas, in which the flue gas flow is used as drying - and transport medium of the moist dust mixture through the mill, the subsequent pipelines and the dust separator is used and
in which the inert gas is subsequently used alone or in addition to the flue gas for further transport and / or intermediate storage of the dust,
characterized by
that the inert gas is heated to a temperature higher than the dew point temperature of the residual moisture of the dust mixture. Method according to claim 1,
characterized by
that the heating of the inert gas to about 30 ^o C above the dew point temperature is carried out. Method according to one of claims 1 or 2,
characterized by
that in interim storage facilities an inner side surface spraying with heated inert gas, in particular CO₂ gas, is carried out. Method according to one of claims 1 to 3,
characterized by
that the heated inert gas used for further transport and / or intermediate storage is used with a volume flow that prevents condensation of the residual moisture contained in the dust or dust mixture. Method according to one of claims 1 to 4,
characterized by
that the heating of the inert gas takes place directly or indirectly in the area of the smoke gas generation, in particular the hot process gas generation. Device for heating inert gas in a mill drying plant with at least one flue gas generator, in particular for a method according to one of claims 1 to 5,
characterized by
that in or after the casing (6), in particular the lining, of the flue gas generator (2; 12) and / or in the flue gas flow (22) a tube coil (7; 21) is provided made of heat-resistant material for heating the inert gas passed through.

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