EP0033971A2 - Discharging device for a of waste material system - Google Patents

Abstract

Discharge device for a pyrolysis plant for treating waste materials in a heatable furnace for discharging the treated solid sulfuric substances with an upright container to which the solid sulfuric substances are fed at the top and which has a blocking device on the underside preventing the solid sulfuric substances from slipping, with a such a height of the container that the carbonization substances contained therein form a gas-tight layer, and a device for maintaining a temperature of ≥ 250 ° C. in the upper region of the carbonization column in a length over which practically no diffusion of the condensable components can occur. Such a discharge device does not require the use of water as a gas barrier and it is also gas-tight at the gas pressures occurring in pyrolysis plants, even with a certain negative pressure in the furnace.

Description

The invention relates to a discharge device for a pyrolysis plant for treating waste materials in a heatable furnace, for discharging the treated solid sulfuric substances.

Yrolyseanlagen _P generally comprise a heated oven, such as a rotary kiln, where the added waste materials to be treated at one end and which are decomposed during their residence time in the furnace in solid Schwelstoffe and carbonization. The carbonization gas is used further, while the treated solid carbonization materials are removed from the furnace via a discharge device in which the discharge tube extends into a water bath which acts as a barrier through which the carbonization gases cannot escape. However, this wet discharge has the disadvantage that the pyrolysis residues become wet when they pass through the water bath. For a dry further treatment, for example for air classification, fuel production or activated carbon production, the water from the wet residues has to be evaporated with considerable energy expenditure. In addition, the fine residue particles agglomerate in a water bath, for example carbon particles with ash particles. It may therefore be necessary to grind the residues, for example for screening after drying.

The invention has for its object to provide a discharge device of the type mentioned, which does not use water as a gas barrier and which is gas-tight even when exposed to the gas pressures occurring in pyrolysis plants, even with a certain vacuum in the furnace. In addition, the aim is to ensure that the residues are free of hydrocarbon condensates, which significantly pollute the leachate when they are deposited.

The solution to this problem is given by an upright container, to which the solid welding substances are fed at the top and the bottom through which the through has slipping of the solid sulphide-preventing device, by such a height of the container that the sulphurous substances in it form a gas-tight layer, and by a device for maintaining a temperature of ≥ 250 ° C. in the upper region of the sulphurous column in a length, through which practically no diffusion of the condensable components can occur. These measures prevent condensation and caking from occurring in the discharged solid sulfuric substances. The solid smoldering substances can therefore be discharged dry. The discharge device is therefore not clogged and the hydrocarbons are not exposed to higher hydrocarbons such as tar, etc.

In the case of a discharge device for a pyrolysis plant with a dust separator for the dust contained in the carbonization gas, the solids outlet of the dust separator can also be connected to a discharge device according to the features of the main claim.

According to a special embodiment, the locking device is formed by a rotatable screw with which the solid carbonized materials or the dust can be transported out of the container.

Alternatively, the locking device can be a plunger. This is preferably arranged to move back and forth in a tube running transversely to the container, the outlet of which is arranged offset with respect to the container. This prevents wires from becoming clogged, such as in a rotating locking device.

According to another embodiment, the locking device is formed by a flap which is biased against the lower opening of the container. Such a locking device automatically opens the lower opening of the same at a certain filling level of the container and allows solid smoldering substances to escape.

The blocking device can also be controlled or regulated by the filling level of the carbonization substances in the container.

According to a particular embodiment, the device for maintaining the temperature is a heating device. Alternatively or additionally, the device for maintaining the temperature can be an insulation of the wall of the container.

An essential embodiment can be seen in the fact that the container has a cooling device in the lower region. As a result, the solid sulfuric substances can be cooled to an outlet temperature far below the gas condensation point and the self-ignition point, so that the solid sulfuric substances cannot glow or burn when they come into contact with air and dust-containing discharge substances cannot explode. The cooling device also has the advantage that the locking device is thermally little stressed.

However, a device can also be provided for inerting the space adjoining the locking device in order to prevent dust explosions.

The container is preferably designed as a tubular shaft. This can widen slightly downwards in the direction of fall to avoid that blockages can occur.

• Fig. 1 zeigt im Axialschnitt eine Austragvorrichtung, die an den Auslaß eines Drehrohrofens angeschlossen ist.
• Fig. 2 zeigt eine andere Ausführungsform einerAustragvorrichtung.
• Fig. 3 zeigt eine weitere, selbsttätig arbeitende Austragvorrichtung.

The invention is additionally described in the forgenden with reference to schematic drawings of several embodiments.

• Fig. 1 shows in axial section a discharge device which is connected to the outlet of a rotary kiln.
• Fig. 2 shows another embodiment of a discharge device.
• 3 shows a further, automatically operating discharge device.

The discharge device shown in Fig. 1 comprises a container 1 which is designed as a tubular shaft and which consists of a circular cylindrical upper region 2, an adjoining frustoconical region 3 and a circular cylindrical lower region 4 adjoining the smaller opening thereof with a reduced diameter. However, the taper must not be so great as to cause blockage in this area. The tubular shaft is arranged vertically, and the inlet 5 above it is connected to the outlet of a rotary kiln 7 via a feed pipe 6. The feed pipe 6 widens in the direction of flow in order to reduce the risk of clogging.

Arranged in the interior of the circular cylindrical lower region 4 is a rotatable worm 8 comprising a plurality of turns, the shaft 9 of which is guided at its upper end in an upper bearing 10 supported on the container and at its lower end in a lower bearing 11. The lower bearing is held in a chute 12 which is adjacent to the outlet 13 of the tubular shaft. The upper bearing 10 can advantageously be omitted, since the screw can then avoid the transport of hard materials.

The circular cylindrical upper area 2 of the container is surrounded by a coil 14 which is connected with its inlet 15 and outlet 16 to a heating medium circuit (not shown). Hot gas can flow through the coil, for example. The upper area 2 and the coil 14 are also surrounded by a housing jacket 17, which together with the wall of the container leaves a space which is filled with an insulating agent 18. The length of this heating and insulating area should be so large that the fixed Smoldering materials in the relevant area of the tubular shaft are kept at a temperature at which no condensation of condensable constituents can yet occur. In most cases, a temperature of more than 250 ° C is required.

Around the circular cylindrical lower region 4, a cooling pipe coil 19 is attached, which is connected with its inlet 20 and outlet 21 to a coolant circuit, for example to running water. As a result, the solid smoldering substances are cooled down to a temperature which is below their self-ignition temperature.

On the wall of the truncated cone-shaped area 3 sits a level meter 22 of a known type, which is designed in such a way that it only responds when the tubular shaft is filled with solid sulfuric materials up to the level of the level meter.

The frustoconical area 3, which forms the transition zone between the heated area and the cooled area, should of course be chosen so large that the cooled area does not affect the heated area.

The discharge device has the following mode of operation.

The solid carbonization materials flowing out of the rotary kiln 7 pass through the feed tube 6 into the tubular shaft 1 and fall at the beginning of the operation down to the screw 8, on which they remain, since the inclination of the screw is chosen so small that the carbonization materials are not can slide outwards on the screw blade. In the course of further operation, the tubular shaft fills up until a certain fill level 23 is reached, at which the fill level meter 22 responds. As a result, the motor 24 is switched on, which drives the worm 8, so that the carbonized material is conveyed out of the tubular shaft. The solid smoldering substances emerging through the outlet 13 reach the chute 12 and are discharged from there to the outside, for example for further treatment for fuel production or activated carbon production and / or to the landfill.

The upper region of the tubular shaft is heated by the coil 14 to such a temperature, usually to at least 250 ° C., that condensable products cannot separate out, so that they do not get out with the solid sulfuric substances.

In the truncated cone-shaped area 3, the solid carbonization materials are compressed due to the weight of the carbonization column above, so that the gas permeability is further reduced. The conicity of the frustoconical region 3 must of course not be so great that it hinders the slipping through of the solid carbonization substances.

As soon as the screw 8 has conveyed some of the contents out of the tubular shaft and the fill level has dropped to the lower fill level 25, the fill level meter 22 switches off, so that the motor 24 driving the screw 8 is de-energized. The container begins to fill up again to the fill level 23, at which the next emptying cycle is initiated.

By a suitable choice of the fill level, it can be achieved that the discharge device is gas-tight and that the gas-tightness is not released even if there is a negative pressure in the rotary kiln 7, since the weight of the smoldering column in the tubular shaft is capable of a certain pressure difference to withstand between the outlet and the inlet.

FIG. 2 shows another embodiment of a discharge device, in which the container 31 comprises a double-walled upper area 32 which merges into a cylindrical discharge tube 33. Outlet end 24 of the rotary tube of the rotary tube furnace protrudes tightly into the double-walled area 32

At the lower end of the discharge pipe 33 is adjacent a conveyor pipe 35 running transversely thereto, in which a screw conveyor 36 is rotatably mounted, which is coupled to a drive motor 37.

The discharge pipe 33 opens at one end region of the delivery pipe 35, while an outlet 38 is provided at the other end region of the same.

The double-walled upper region 32 of the container 31 is flowed through by hot gas, which can be removed at a suitable point in the pyrolysis plant (not shown), so that the container is heated in this region.

The lower area of the discharge pipe 33 and the delivery pipe 35 are surrounded by a cooling coil 39, which cools the solid carbonization substances to a temperature below the self-ignition temperature thereof.

A lower fill level sensor 40 and an upper fill level sensor 41 are arranged in the upper region of the discharge pipe 33. These are designed in such a way that they respond when the solid smoldering materials reach a level sensor.

The level sensors are connected to a control circuit (not shown) for the drive motor 37, which is designed such that the upper level sensor 41, when it is covered by carbon dioxide, switches the drive motor on, while the lower level sensor 40 then switches off the drive motor 37 each time when it is no longer covered by carbonization.

Such level controls are known per se and do not form one Part of the invention.

The mode of operation of the discharge device according to FIG. 2 is similar to that of the discharge device according to FIG. 1, so that a further description is unnecessary.

Figure 2 shows a further, automatically operating discharge device. The container is designed similarly to that according to the embodiment according to FIG. 2, only the lower region of the container being designed as a discharge tube 44 which widens conically towards the outlet. The upper region 43 is surrounded by an insulating material jacket 45 which extends downward to approximately half the length of the discharge tube 44. The thermal insulation resistance of the insulating jacket 45 is dimensioned such that the solid carbonization materials which are in the area of the container surrounded by the insulating jacket do not cool below 250.degree.

The outlet end of the discharge pipe 44 is chamfered and projects into a collecting container 46. On a hinge 47 attached to the discharge tube 44, a closure flap 48 is articulated, which forms a two-armed lever, one side of which is plate-shaped and can close the outlet of the discharge tube 44 and the other end of which carries a counterweight 49, which ensures that the closure flap The aim is to close the lower opening of the discharge tube 44.

If, during operation of the discharge device, the solid carbonization materials have reached a certain fill level, the pressure exerted on the closure flap is so great that the counterweight 49 can no longer keep the opening of the discharge tube closed and that solid carbonization materials therefore emerge from the opening until the closure flap the solid column in the container as we can keep the balance. This way a simple, less fault-prone regulation of the fill level.

In the case of a negative pressure in the discharge system, the length of the carbonization column must of course be chosen so large that the solid carbonization materials are not raised and loosened by the greater pressure acting on the underside of the container in order to ensure gas-tightness. This is certainly achieved if the weight of the sulfur column in the container per unit area is greater than the pressure difference between the bottom and the top of the sulfur column.

Inertisieren kann der Rückstand beispielsweise heiß in

Sammelgefäß ausgetragen werden, in das Wasser eingedüst

in einer Menge, daß die ausgetragenen Stoffe zwar nach

vor trocken bleiben, jedoch abgekühlt werden.

The residue can be inertized, for example, hot in

Collection vessel are discharged, injected into the water

in an amount that the discharged substances after

stay dry before, but cool down.

Claims (13)

1. Discharge device for a pyrolysis plant for treating a waste in a heatable furnace for discharging the treated solid sulfuric substances, characterized by an upright container to which the solid sulfuric substances are fed at the top and which prevents the solid chemical substances from slipping on the underside Locking device, by such a height of the container that the sulfuric substances contained therein form a gas-tight layer, and by its device for maintaining a temperature of 250 250 ° C. in the upper region of the sulfurous column in a length over which there is practically no diffusion of the condensable components can occur more. 2. Discharge device according to claim 1 for a pyrolysis system with a dust separator for the dust contained in the carbonization gas, characterized in that the solids outlet of the dust separator is also guided to a container to which the separated dust is fed at the top and one on the underside Has locking device. 3. Discharge device according to claim 1 or 2, characterized in that the locking device forms a rotatable screw (8). 4. Discharge device according to claim 1 or 2, characterized in that the locking device is a push sel (36). 5. Discharge device according to claim 4, characterized in that the plunger (36) is arranged to move back and forth in a tube (35) extending transversely to the container, the outlet (38) of which is arranged offset with respect to the container. 6. Discharge device according to claim 1 or 2, characterized in that the locking device forms a flap (48) bearing against the lower opening of the container under prestress. Discharge device according to claims 1 to 6, characterized in that the blocking device is controlled or toggled by the height of the carbonized substances in the container. 8. Discharge device according to claim 1 to 7, characterized in that the device for maintaining the temperature is a heating device. 9. discharge direction I Auschuch 8, characterized in that device for maintaining fer temperature is an insulation of the wall of the container. 10. Discharge device according to claim 1 to 9, characterized in that the container has Auhlvorrichtung (19) in the lower region. 11. discharge device according to claim 1 to 9, characterized characterized in that a device is provided for inerting the connecting to the locking device send room. 12. Discharge device according to claim 1 to 11, characterized in that the container forms a tubular shaft (44). 13. Discharge device according to claim 12, characterized in that the tubular shaft widens slightly conically downwards in the full direction.

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