EP0177524A1 - Method and plant for producing active formed coke as granulate on the basis of pretreated pit coal - Google Patents

Abstract

The process for manufacturing active molded coke as an aggregate on the basis of pretreated coal provides for passing the pre-molded aggregate through different treatment zones of a well (1) and exposing it on the course to the carbonization process and activation, as well as further processing. The aggregates are brought in flat heaps adapted to the cross section of the well and of the same thickness relative to the cross section of the latter, they are supported in stages by grids (2) with free intervals between them. By maintaining predetermined residence times in the various stages, the heaps pass through the treatment zones and the well from top to bottom. In the treatment zones, they are crossed by gases or vapors (31) introduced laterally in the intervals separating neighboring piles. The passage of the heaps from one grid to the other is carried out by means of a controlled movement leaving at least part of the grid bars (15, 16) from the plane of the grid, so that the aggregates reform on the next grid. a pile of the same thickness with respect to the cross section.

Description

Process and device for the production of activated molded coke as granules based on pretreated hard coal

The invention relates to a method and a device for producing active molded coke as granules on the basis of pretreated hard coal, in which preformed granules are conveyed through different treatment zones of a shaft and heated in these zones by gases or vapors fed in and out laterally, heated. with steam or C0 _? -Gas or a mixture of water vapor and CO -Gas activated and aftertreated and cooled.

It is known to produce activated molded coke on the basis of pretreated hard coal as granules or as a granular product by pulverizing the hard coal with a binder and converting it into the form of granules, which are subsequently smoldered and activated in order to obtain a correspondingly granular or granulated product. In the pretreatment of hard coal, ash removal or extraction or oxidation can also take place before pulverization. Known binders for the pasting of the pulverized hard coal include hard coal and wood tar, inorganic gels such as silica gel, and iron or aluminum hydroxides, also in combination with neutralizing substances such as sodium hydroxide solution or lime.

It is also known for the production of activated coke to convey the pretreated products provided for this purpose through a shaft which has the various treatment zones mentioned above, in which the welding, heating and activation by laterally supplied and removed gases or vapors he follows. In the known method, the material to be treated, which is conveyed through the shaft, is deflected several times in opposite directions in the form of a column of material in order to achieve a larger reaction area and an effective mixing of the reactants, and the gases or vapors flow through it in the direction transverse to the column of material. In another embodiment, the material to be treated is passed through sleeve-shaped internals which pass centrally over the shaft from top to bottom and the column of material is acted upon and flowed through by treatment gases introduced from the side.

The known methods require relatively long dwell times in the individual zones in order to achieve the necessary heat and material exchange, in particular when the flow occurs in the vertical direction of the pillar, so that a large amount of energy is required both for achieving the flow and for the transferred heat are required. In addition, there is an uneven Treatment of the good particles in the good column by the pronounced flow profile. Finally, considerable abrasion losses already occur during the production of the activated coke, since the good particles located in the lower area of the good column are under the static pressure of the good column and, when they move, correspondingly high frictional forces with neighboring good particles or the internals in the shaft are unavoidable .

The invention is based on the object of developing a method of the type described in the introduction in such a way that the aforementioned disadvantages are avoided and in all treatment zones a uniform application or flow around all the granules with very favorable fluid-mechanical effectiveness, i.e. a favorable ratio of transmitted power to applied mechanical power is achieved.

To solve the above problem, the method mentioned at the outset is characterized by the features mentioned in the characterizing part of claim 1.

The shaping of the granules with a uniform size results in approximately equal gap spaces in the individual piles, which are of particular importance for the gases or vapors to flow through the piles in the individual treatment zones. In connection with the flat piles with the same layer thickness over their cross-section, there is approximately the same flow resistance at all points across the cross-sectional area of the piling, so that even flow through the piles is achieved with a uniform flow. The uniform inflow of the individual piles in the area of the introduction of the gases or vapors into the shaft is ensured by the supply of the gases or -. -

Vapors reached in the free spaces between adjacent heaps. When several gases are stacked on top of one another through the gases or vapors, any irregularities in the flow, i.e. locally different flow velocities or local differences in the pressure of the gases or vapors emerging from the previous heap are compensated again, so that these irregularities cannot have a disadvantageous effect over the entire flow path of the gases until they are removed.

As a result of the uniform treatment of all granules and as a result of the intensive flow through the gap spaces with simultaneous swirling of the gas in these spaces, fresh gas particles repeatedly come into contact with the surfaces of the granules, so that a very intensive heat and material exchange is achieved. by which a considerable reduction in the reaction time is achieved.

The subdivision of the material to be treated consisting of the granules into flat and even piles arranged at a distance from one another also means that the granules are not subjected to an increased static pressure at any stage of their treatment, which would lead to the undesired signs of abrasion.

It is important, however, that the piles maintain a constant layer thickness as they travel through the treatment zones. The controlled moving out of at least some of the grate bars from the grate level results in a dissolution of the pile located on these grate bars, wherein the control of the movement of the grate bars mentioned achieves the desired uniform trickle flow and on the next one Rust can in turn form a pile with the same layer thickness over the cross-section. Depending on the shape and size of the good particles, the most favorable movement sequence of the grate bars can be determined by appropriate previous trickle tests and the control for the movement of the grate bars can then be set accordingly. When the piles are dissolved, the movable grate bars also simultaneously dissolve any good bridges that may have arisen. A time-controlled lowering or a time-controlled lifting of the movable grate bars can be provided.

The formation of a pile with a layer thickness that remains constant over the cross section must already take place when the granules are transferred into the shaft after they have taken place. The granules required for the pile are dosed.

It is expedient if the piles during Ver¬ residence times in the carbonizing of the carbonization in contrast ^• Strom flow through. The carbonization gas is therefore directed through the piles in the opposite direction to the conveying direction of the granules when they are transferred from rust to rust. The smoldering zone can comprise several heaps through which the smoldering gas flows in succession. The carbonization gas usually has a temperature of around .00 ° C. The countercurrent flow of the carbonization gas through the heaps allows the granules in the pile to be reached or slightly exceeded when the flow rate of the gases is set, so that the granules in the carbonization zone are caked or glued together by adjusting the flow rate of the carbonization gas accordingly largely prevented can be. The flow rate, based on the free cross-section of the shaft, can be up to 5 m / sec. be.

It is particularly expedient if, during the dwell times in the smoldering zone, the piles are partially and locally shielded from flowing through the smoldering gases and flowed through in the respective other areas until the loosening point is reached or exceeded. In this way, an alternating partial movement of the granules in the pile or else a partial shifting from the areas through which the flow is flowing to the areas through which no flow occurs can be achieved, with the return of the previously shifted granules always being able to be achieved by the local change in the partial flow.

During the treatment of the granules, it is expedient if the piles in the heating, activation and post-treatment zone are flowed through in one direction during one or a few dwell times and in the opposite direction during other dwell times, since this results in Heat gradients in the piles is reduced.

It is particularly advantageous if, in a further development of the invention, the heaps in the cooling zone are sprayed with water and the water vapor generated in the cooling zone is fed to the heaps of at least one of the preceding treatment zones. As a result, in addition to the cooling effect, at least a considerable proportion of the water vapor required for the previous treatment of the granules is obtained, and a considerable energy saving is thus achieved. Devices for carrying out the method described above proceed from a built-in shaft for receiving the granules to be conveyed through the shaft, which is connected to devices for supplying and removing the gases and / or vapors and with side inlets and outlets Outlet openings for the gases is equipped. According to the invention, this device is characterized by the features mentioned in claim 6.

It is useful if the device for supplying and evenly distributing the pre-dosed piles of egg nem in an entry lock over the shaft cross-section has a movable box with a grate as the bottom, which corresponds to the rust in the shaft in its design and can be operated in the same way.

It is also advantageous to provide, at least between adjacent grates of different treatment zones, a partition wall formed from pivotable slats and which can be moved into the closed and open positions by adjusting the slats. Such dividing walls can also be provided in the area of the entry of the piles into the shaft and their discharge from the shaft. These dividing walls make it possible in a particularly simple manner to separate the treatment gases which are led through the piles in the individual zones and which have a different composition and also different temperatures.

In order to enable the already described partial flow through the heaps provided in the smoldering zone, it is advisable to provide a grid-shaped insert for forming parallel flow channels immediately below the grates in the smoldering zone of the shaft and flaps in the streams that can be rotated about horizontal axes. Arrange channels which can be pivoted alternately in groups in the shaft plane or perpendicularly to the fields of a chessboard. A simple constructive solution for the arrangement of the pivotable flaps is obtained if two flap horizontal axes are provided for each flap row for the alternate arrangement and pivoting of the flaps in groups.

Further details on the special design of the grates with their movable grate bars and their configuration in the form of structural units can be found in claims 11 to 15.

In order to be able to vary the height of the shaft in accordance with the respective requirements and also to enable prefabrication, the shaft must be in an appropriate configuration of the device. ring-shaped closed module parts each with a grate, and in at least some of the module parts in the walls the passage openings for the supply and discharge of the gases are provided.

In another variant of the shaft structure, the grids are designed as structural units which can be inserted laterally through closable window openings into the shaft walls. This solution has the advantage that the grates can be exchanged relatively easily if they become unusable, or if grates with different distances between the grate bars are to be used in the shaft due to different goods.

By leaving the free spaces provided between adjacent piles, it is possible to place them below the fixed grate bars Shaft walls on the inside of the shaft to provide recesses for receiving the actuation devices for the movable grate bars or for the structural units formed by them, and to assign drive devices for the actuation devices outside the shaft wall.

In order to prevent the granules from closing the gap spaces between the grate bars with certainty, it is advisable to design the grate bars so that they have an undercut profile in cross-section in their upper part and with interchangeable, rider-shaped profile parts are equipped. These are expediently formed as horseshoes with projections pointing in the longitudinal direction of the grate bars as stops with adjacent profile parts. By means of these rider-shaped profile parts, the proportion of the free flow area as a whole or else locally per grate can be changed while the spacing of the grate bars remains the same. In addition, the use of rider-shaped profile parts of different cross-sections on one and the same grate can influence the formation of the trickle stream when the movable grate bars are transferred into the opening position. It is therefore possible to use the rider-shaped profile parts to act both on the flow through the piles and on the formation of the trickle stream in order to achieve uniformity.

Since temperatures in the shaft between 400 and 950 ° C prevail, correspondingly heat-resistant materials must be provided for the internals in the shaft. It is advantageous if the grate bars and the other load-bearing parts of the grates and the grate-shaped inserts and the flaps held therein consist of ceramic materials. In order to achieve the above-described cooling of the lowest piles in the shaft in a particularly effective manner and at the same time to generate at least part of the water vapor required in the previous treatment zones, it is advisable to use a spray device above at least one of the piles in the cooling zone ¬ device for the supply of water.

The drawing shows a schematic representation of an exemplary embodiment of a device for carrying out the method and details of this device.

Show it:

1 shows a longitudinal section through a shaft for the production of active molded coke as granules according to the invention with a schematic representation ^{* of} the process gas guide,

2 an enlarged view of part of the sectional image according to FIG. 1 at the level of a grate from which details of the grate arrangement can be seen,

3 is a plan view of the arrangement of FIG. 2,

4 a total of four possible positions of the grate bars in their arrangement and design according to FIGS. 2 and 3,

5 is a perspective view of two grate bars with partly mounted rider-shaped profile parts,

6 shows a partial top view of two parallel grate bars according to FIG. 4 with rider-shaped profile parts applied, Fig. 7 shows a partial longitudinal section through the shaft

1 in the area of a pile of the smoldering zone,

8 shows a view from below against the flaps according to FIG. 7 arranged distributed over the shaft cross section,

Fig. 9 is an enlarged cross sectional view showing one of the flaps By J of FIGS. 6 and 7 _"

Fig. 10 is a partial longitudinal section through a shaft with grids that can be inserted laterally.

The shaft shown in FIG. 1 has a shaft opening designated overall by 1 and has a square or rectangular cross section. In the shaft grids 2 are arranged at intervals one above the other in the walls so that chambers 3 are formed between adjacent grids, which only partially. are filled by flat piles 4 from the granules to be treated in the shaft on the basis of pretreated hard coal for the production of active molded coke, so that a free space remains between the adjacent piles 4.

In the example shown, the shaft is composed of module parts 5, which are closed in a ring and are arranged one above the other, each with a grate 2 held therein, so that the shaft is provided by a corresponding number of module parts 5 at different heights and with correspondingly different. Number of floors can be er¬.

At its lower end, the shaft has an outlet opening 9 that can be closed by a slide 10 equipped for the discharge of the activated coke granules treated in the shaft. A conveyor 10a for the further conveyance of the granules emerging from the shaft can be seen below the shaft.

The shaft is closed at the top by an end housing designed as an entry lock 6. In the laterally protruding part of the end housing 6 there is a schematically only indicated metering device 7, in which the quantity of the pretreated granules intended for a pile 4 is received and from which it forms a flat pile with the same layer over the cross section thickness is transferred into a sliding mold box 8. This is closed at the bottom by a grate 2a, which corresponds to the grates 2 in the module parts 5 of the shaft 1 and which is equipped with the same actuating devices to be described as the grilles 2 in the shaft, so that after the transfer of the molding box 8 in the position above the free shaft cross-section to transfer the pile located in the mold box 8 onto the grate 2 which limits the top chamber 3a upwards while maintaining a uniform layer thickness over the cross-section of the pile.

Like the molding box, the metering device 7 can have a grate corresponding to the grates 2 in the shaft and an additional device for leveling the surface of the pile to be picked up. The interior of the shaft 1 with the piles 4 located therein can be divided into a total of five zones, from top to bottom into zones I to V indicated on the right next to FIG. 1. The top zone I forms the smoldering zone. Zone II, which adjoins at the bottom, is the heating zone. The keep going down Zone III is the activation zone. This is followed by the post-treatment and cooling zones as zones IV and V.

In the example shown, the zones I to V mentioned in the interior of the shaft 1 are each separated from one another in terms of flow technology by dividing walls 11 formed from pivotable slats and which can be moved into the closed and open positions by adjusting the slats. All slats are located in FIG. 1 in the closed position so that the partitions 11 are effective.

Between the uppermost pile in the shaft and the further pile located beneath it is arranged a further similar partition 11a, which brings the smoldering zone I together with a barrier pile located under the partition 11a and not flowed through upwards against the respectively newly introduced into the shaft Heap limited and fluidically delimited.

Immediately below the grates of the smoldering zone I, grate-shaped inserts 12 can be seen in connection with flaps 13 _' , which allow a partial flow through the piles located on these grates in the smoldering zone I. Details of the grid-shaped input ^'sets 12 and the flaps 13 are described in connection with Figures 7 through. 9

The grids arranged in the shaft 1 consist, according to FIGS. 2 to 4, partly of fixed grate bars 14 and partly of movable grate bars 15 and 16. The latter can be moved upwards relative to the fixed grate bars 14 from the ros plane in order to free the spaces between adjacent ones Temporarily enlarge grate bars. In Fig. 2, the position of the grate bars 14 to 10 in the grate plane is shown in the left part, while in the right part the grate bars 15 and 15 are shown in differently raised positions with respect to the grate plane. Crank or swivel arms 18 are provided in niche-shaped recesses 17 on the inside of the shaft for lifting the grate bars 15 and 1β and can be pivoted from the outside via an actuating shaft 19. The movable grate bars 15 and Iβ are elongated compared to the fixed grate bars 14 and are combined to form a unit which can be raised and lowered, the extensions of the grate bars 15 and 16 taking the form of bent portions 15s of different lengths. or 16a. The result of this is that when the crank arm δ is pivoted about the pivot axis 19, the

Grate bars 15 and 1 can be transferred to different heights, as can be seen in the right half of FIG. 2.

Instead of lifting the movable grate bars 15 and I ^β , conversely, a lowering of these grate bars can also be provided in such a way that the grate bars 15 and 1 assume different positions relative to one another. 4 shows four variants of these different positions of the grate bars 14 to 10 relative to one another, the starting position of the grate bars and the hatched possible end positions of the grate bars being shown in dashed lines.

In practice, the grate bars shown schematically in FIGS. 2 and 3 have the shape shown in FIGS. 5 and β. The grate bars can be designed as solid or hollow profile bars, the possible cavity in the case of the hollow profiles being shown in dashed lines in the hatched sectional area in FIG. 5 The grate bars have an undercut profile

20 and are equipped with rider-shaped profile parts 21. These rider-shaped profile parts 21, which are held interchangeably on the grate bars, have a horseshoe shape and show projections 22 pointing in the longitudinal direction of the grate bars as stops with adjacent rider-shaped profile parts. When the rider-shaped profile parts 21 are packed tightly on the grate bars, the grate bars have a shape which can be seen in the top view of FIG. 6 on two adjacent grate bars. 6 also shows that in the case of adjacent grate bars the tab-shaped profile parts are expedient

21, viewed in the longitudinal direction of the adjacent rods, are arranged offset from one another.

The rider-shaped profile parts 21 cause the bottom in each pile layer of the granules can not verschlie¬ SEN the spaces between adjacent grate bars, but the ^'granules are forced into a mutually offset position so that the most in the unter¬ layer between the granules remaining interstices enable a uniform inflow and inflow of the treatment gases into the piles located on the grates. The rider-shaped profile parts 21 can have a different diameter at a predetermined spacing of the grate bars, so that the percentage of the free flow cross-section through the grates can be adjusted accordingly or changed overall or locally.

The arrangement and design of the grate-shaped inserts 12 and the flaps arranged therein, as are used in the smoldering zone I, can be seen from FIGS. 7 to 9. Due to the grating-shaped insert 12, flows running parallel to one another over the entire cross-sectional area of the grating 2 or pile 4 channels 23 are formed, in each of which one of the pivotable flaps 13 is held. The flaps 13 are held in the flow channels 23 corresponding to the fields of a chess board so that flaps lying next to one another each have a different position. In order to be able to adjust the positionally identical flaps 13 of each row, two superimposed horizontal axes 24, 25 according to FIG. 9 are provided, on which the flaps 13 of each row are held alternately. In the practical embodiment according to FIG. 9, the flaps 13 held on the axis 25 accommodate the axis 24 of the respectively adjacent flaps in a recess, without these axes 24 hindering the pivoting movement of the flaps 13 held on the axes 25. In this way it is possible to move all flaps into the locked position or all flaps into the open position or the adjacent flaps into different positions.

Instead of the modular construction of the shaft 1 described in connection with FIG. 1, the shaft wall can also be designed as a continuous wall and, in accordance with the example in FIG. 10, have window openings 2β into which the gratings 2 are in the form of the structural units already mentioned can be inserted laterally. The gratings 2 are held in groove-shaped recesses 27 of the side shaft walls via support devices 28. To close the window openings 2β in the shaft wall 1, an adapted filler piece 29 is used in connection with a cover plate 30 which can be screwed to the shaft wall after the filler piece 29 has been inserted. The aforementioned design makes it possible to replace the grids 2 designed as a structural unit at short notice with little effort. An example of the method designed according to the invention will now be described in connection with FIG. 1. For this purpose, a possible process gas flow for the production of activated coke granules is shown schematically and simplified in FIG. 1 in the shaft shown. The respective arrows indicate the direction of flow of the gases or vapors.

In the example, all gas inflow openings 31 are located in the right-hand shaft wall, while the outflow openings 32 are shown in the left-hand shaft wall.

According to the example shown, separate gas circuits are provided for zones I to IV, which are similar in structure to one another. In the example shown, a mixture of water vapor and CO _{2 is used} as the activation gas. It is assumed that a mixture of water vapor and CO _{p is used} as the inert gas for the smoldering zone I and for the preheating zone II. And finally also for the aftertreatment zone IV as inert gas.

In the individual circuits, the blowers are each with G, the burners in which the after-combustion of the respective reaction gases emerging from the shaft takes place with B, the heat exchangers with W and the mixing devices in which water vapor and CO- are mixed with the fuel gases are designated by M. The supply lines for air have the label L, the lines carrying the water vapor D and the lines supplying the CO _p gas have the label C.

The possible interlinking of the heat exchangers W is not shown in the drawing. In the example, it is assumed that in the cooling zone V, the heaps located there are cooled exclusively by spraying water on a heap by means of the spray device 33, so that in the cooling zone, into which the heaps are at a temperature of about

800 C occur, the water vapor is generated, which is led to a smaller part in the circuit, while the predominant part is led via the line D starting from the cooling zone to the circuits of zones I to IV, so that in the Process shown the required steam for the process in the cooling zone V is generated. In the cooling zone, the aggregates are flowed through in counterflow. The heaps are cooled down to approximately 120 ° C. before the lowest heap is transferred to the further conveyor 10a through the opening of the grate using the movable grate bars via the discharge opening 9 with the slide 10 open. After returning the grate bars of the lowest grate to the closed position, the grates that follow upwards are opened one by one and the partitions

11 and 11a transferred to the open position of the slats. The flaps 13 in the grate-shaped inserts

12 are all transferred to the open position, so that the piles can be transferred unhindered one after the other in each case in the form of a trickle stream onto the next grate, in order to form a piling there again with a layer thickness that is constant over the cross section. When the transfer of the piles to the next grate has ended, the partition walls 11 and 11a are brought back into the closed position by pivoting the slats and the flaps 13 in the grate-shaped inserts 12 are brought into the desired position for the respective process in the smoldering zone Position transferred depending on whether a partial movement of the granules of the piles located in this zone is desired or not. The uppermost grate released by the movement of the piles is again loaded by transferring the molding box 8, which has in the meantime been filled with a pile from the metering device 7, the transfer of the piling from the molding box 8 taking place in the same manner as this in connection with the other grates 2 in the shaft 1 has already been described.

In the smoldering zone, in the example shown, two pebbles are flowed through in succession by the smoldering gas. The carbonization gases have a temperature of around 400 ° C. In order to reliably prevent the carbonization gases from escaping upwards, a pile is provided below the partition 11a, which is not flowed through by the carbonization gases and serves as a bulky charge.

The heaps in the smoldering zone are flowed through over a period of two dwell times and from there reach heating zone II, in which, according to the example, they are again flowed through during two dwell times. Here, however, the flow takes place in opposite directions on the two grates provided there. In the heating zone, the inert gas consisting of water vapor and CO _p flows through the heaps at a temperature of 900 ° C.

In the following activation zone, four grates are provided in the example, so that the activation gas flows through the piles for four dwell times, again from floor to floor in alternating directions. The activation gas supplied has a temperature of approximately a9. ö ° C. The reaction gas emerging from the activation zone, which is produced in a larger volume as a result of the chemical reaction than the supplied activation gas, can differ from the illustration 1 in the circuit of the heating zone in order to at least partially cover the gas required there.

The subsequent post-treatment zone IV in turn provides that the piles are post-treated on four floors, that is to say they spend four dwell times in this zone, the piles being flowed through from floor to floor in opposite directions, namely by a post-treatment gas at one temperature of about 800 C.

The heaps are then cooled on two floors with the aid of the sprayed-in water, as has already been described. It is provided that the spray device 33 above the lowest pile in the

Cooling zone is arranged so that the water vapor arising in this zone is heated by the countercurrent flow in the upper store in the cooling zone before it is passed on via line D to the previous zones described.

The hard coal used to produce the granules to be activated in the shaft can be pretreated in a known manner by extraction or oxidation. Depending on the intended subsequent use of the activated coke particles, their treatment after activation in the aftertreatment zone is possible with very different gases or gas compositions and can also be carried out at very different temperatures.

1, there is an intensive flow through the heap, in each case in the direction rotated to the layer level, with the supply and discharge of the gases and the free spaces between the heap providing an equal moderate inflow and outflow over the cross-sectional area of the heaps is ensured. The abrasion of the granules is extraordinarily low during the treatment in the manner described, since the granules are not exposed to any greater static pressure and do not have to be moved under such a pressure, as is the case with continuous fillings or columns of material.

As a result of the intensive flow of the individual gases through the heaps and as a result of the intensive and uniform flow around all of the individual granules of the heaps, there are extremely short reaction times and thus correspondingly short dwell times. The gas compositions, their temperatures and also the flow velocities in the individual zones can be varied within wide limits and adapted to the particular requirements in order to achieve particularly high effectiveness.

Claims

Expectations

1. A process for the production of active molded coke as granules on the basis of pretreated hard coal, in which preformed granules are conveyed through different treatment zones of a shaft and in these zones are smoldered, heated, heated with water vapor or by gases or vapors fed in and out laterally CO _p - gas or a mixture of water vapor and CO _p gas are activated and aftertreated and cooled, characterized in that granules of uniform size with longitudinal and transverse dimensions or a diameter of 6 to 25 mm are formed and shaped even, flat piles adapted to the shaft cross-section are transferred with the same layer thickness over the cross-section and are supported in the shaft in each case by gratings one above the other, leaving free spaces and after predetermined dwell times in the individual floors with the lowest pile by discharging it from top to bottom the shaft is conveyed through The gases or vapors flow through the piles during the dwell times on the grates in the treatment zones by introduction into the free spaces between adjacent piles and discharge from other spaces in each case perpendicular to the layer level, and that the piles follow of the respective dwell time on the individual grates by a time-controlled removal of at least some of the grate bars from the grate level and the granules in the form of a uniform trickle stream are transferred to the next grate in such a way that they in turn accumulate over form the cross section of the same layer thickness.

2. The method of claim 1, d a d u r c h g e ¬ k e n n z e i c h n e t that the pebbles during the dwell times in the smoldering zone are flowed through by the carbonization gas in countercurrent.

3. The method according to claim 2, which also means that the piles alternate locally during the dwell times in the smoldering zone and are partially shielded from flowing through the smoldering gases and flowed through in the respective other areas until the loosening point is reached or exceeded.

4. The method according to any one of claims 1 to 3, characterized in that the heats in the heating, activation and post-treatment zone are flowed through in one direction during one or a few dwell times and in the opposite direction during other dwell times .

5. The method according to any one of claims 1 to 4, d a ¬ d u r c h g e k e n n z e i c h n e t that the heaps in the cooling zone are sprayed with water and the water vapor arising in the cooling zone

Pile is supplied to at least one of the upstream treatment zones.

6. Device for performing the method according to one of claims 1 to 5 with a built-in

Shaft for receiving the granules to be conveyed through the shaft, which is connected to devices for supplying and discharging the gases and / or vapors and is equipped with lateral inlet and outlet openings for the gases, characterized in that the interior of the The shaft (1) is divided into chambers by grids (2) and in the upper part of the shaft a device (7, 8) for feeding pre-dosed piles of the granules, which only partially fill the chambers, and for evenly distributing the granules over the shaft cross-section onto the The uppermost grate provides that all grates at least partially consist of movable grate bars (15, lβ) with actuating devices (18, 19) and controllable drive devices assigned to them for temporarily and time-controlled enlargement of the free spaces between adjacent grate bars by moving them out some of the grate bars consist of the grate level.

7. The device according to claim 6, characterized in that the device for supplying and evenly distributing the pre-formed piles has a molded box (8) with a grate (2a) as the bottom, which is movable in an entry lock (β) over the shaft cross section its training corresponds to the grate (2) in the shaft (1) and can be operated in the same way.

8. Apparatus according to claim 7 or 8, characterized in that at least between adjacent grids (2) different treatment zones (I to V) each have a partition formed from pivotable slats and by moving the slats into the closed and open position convertible (11; 11a) is provided.

9. Device according to one of claims 6 or 8, since ¬ characterized in that directly below the gratings (2) in the smoldering zone (I) of the shaft (1) each have a grate-shaped insert (12) to form parallel flow channels ( 23) is provided, and that flaps (13) which can be rotated about horizontal axes (24, 25) are provided in the flow channels and which, according to the fields of a chessboard, can be pivoted alternately in groups into the shaft level or perpendicularly thereto.

10. The device according to claim 9, d a d u r c h g e k e n n z e i c h n e t that two flap rows horizontal axes (24, 25) are provided for the alternate arrangement and group pivoting of the flaps (13) per flap row.

11. Device according to one of the preceding claims, characterized in that the movable grate bars (15 _» l6) of each grate (2) form at least one structural unit by a connection of their ends, which by the actuating device (s). (18, 19) and the controllable drive device can be moved out of the plane of the fixed grate bars (14).

12. The apparatus according to claim 11, characterized in that the or each of the movable grate bars (15 _» lβ) formed by means of a lifting device in a plane outside the plane of the fixed grate bars (14) can be raised and held in the plane of the fixed grate bars .

13 i Device according to one of the preceding claims, ^'by in that the movable grate bars (15jlβ) of the or each module via the fixed grate bars (14) also ver¬ extended formed and these extensions (15a, lβa) are interconnected, and that as Lifting device a crank mechanism (18, 19) engaging on the interconnected ends of the grate bars is provided.

14. Device according to one of the preceding claims, d a d u r c h g e k e n e z e i c h n e t that several units of movable Ros rods (15, 16) are provided per grate (2) and can be transferred to different levels outside the plane of the fixed grate bars (14).

15. Device according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the grate bars (14 to 16) are designed as hollow profile bars.

16. Device according to one of the preceding claims, dadurchge ke nnzeich that the shaft (1) from ring-shaped closed module parts (5) with a grate (2) is constructed and in at least some of the module parts in the walls through openings (31,32) are provided for the supply and discharge of the gases.

17. Device according to one of the preceding claims, that the grids (2) are constructed as structural units which can be inserted into the shaft walls laterally through closable window openings (26).

18. Device according to one of the preceding claims, characterized in that in each case below the fixed grate bars (14) in the shaft walls on the inside of the shaft recesses (17) for receiving the actuating devices (18,19) for the movable grate bars (15, lβ) or for the provided by these structural units and drive devices for the actuating devices are arranged outside the shaft wall.

19. Device according to one of the preceding claims, characterized in that the grate bars (14 to Iβ), seen in cross-section, have an undercut profile (20) in their upper part and are equipped with pushed-on, replaceable, rider-shaped profile parts (21), which close Prevent the spaces between adjacent grate bars through the goods.

20. The apparatus of claim 19, d a d u r c h g e - k e n n z e i c h n e t that the rider-shaped

Profile parts (21) are horseshoe-shaped with projections (22) pointing in the longitudinal direction of the grate bars as stops with adjacent profile parts.

21. Device, according to one of the preceding claims, that the grate bars (14 to lβ) as well as the other load-bearing parts of the grates and the grate-shaped inserts (12) and the flaps (13) held therein consist of ceramic materials.

22. Device according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that above at least one of the heaps of the cooling zone (V) a spray device (33) is provided for the supply of water.