DE3611948C2 - - Google Patents

Description

The invention relates to a device control device for a rotary roaster, burner and / or calciner, according to the preamble of claim 1.

Rotary heating chamber furnaces with non-rotating stirring hooks, roasting Shovels, scratches or the like are usually used for the con continuous coking, removal of volatile or vaporizable substances during and / or calcining, Burning, roasting or the like of carbon-containing materials, such as non-caking coals, anthracite coal, wood products, green petroleum coke, pellets or bri chains that controlled percentages of bituminous verko kender coal and other carbonaceous materials or inert materials either with or without contain a bituminous binder. You can also for calcining, burning, roasting or the like of dolomite, lime  stone and cement rock, for the recovery of calcium oxide from carbonate sludge, for the decomposition of carbonates, Sulfonates and chlorides, for the reactivation of active coal and Like. Be used.

Examples of such ovens are in the US patents 34 48 012, 34 70 068, 34 75 286, 35 94 287, 36 12 497, 36 52 426 and 37 63 013 described and shown. As a general rule Such an oven includes a heating chamber which is around a vertical axis rotates and its bottom to a central one Outlet sloping downward, as well as a cylindrical Chamber known as an emptying shaft or deep furnace and is narrowing below the outlet Drain opening extends, and a horizontal rotation emptying table, which is arranged below. It's upper Half of the stove top of the heating chamber, stirring hooks, roasting scoops, scratches o. The like. Positioned so that they follow the material to be treated move inwards to the emptying shaft or deep furnace Customers are attached above the emptying table, which turns the material on the table into a Ent Move the discharge passage or channel.

A number of operators of rotary chamber calciners, burners or roasters have observed a phenomenon called "Flooding" is referred to as d. H. a spontaneous quick Emptying material from the emptying shaft on the emptying table. A "flood" then occurs when a material with the rotary heating chamber furnace is trading, which is an unusually large proportion of fine Contains particles. Under the name "fine particles", As used here, such part should in particular that are understood through a sieve, the square openings with a side length of 1.6 mm or less. Ent caused by the phenomenon of "flooding"  there are operational problems and possibly also safe problems.

In principle, this phenomenon of flooding can master by means of a "snail", as in a Ent emptying control device of the type mentioned, which in US-PS 34 75 286 is provided. By emptying the material to be treated from the rotating discharge shaft into the non-rotating screw a spiral-shaped material casting is achieved in it. Such a screw is not only in the rotary heating chamber oven usable according to the aforementioned document, in which the axis of rotation of the emptying shaft concentrically that of the rotary discharge table, but also in such a rotary heating chamber furnace, in which these at the axes of rotation are eccentric to each other, as z. B. in the US-PS 37 63 013 is described.

The object of the invention is an emptying tax to design the device of the type mentioned in such a way that so that a "flooding" is better prevented, which in the Treatment of materials arises that make up a large proportion have fine particles.

According to the invention, this object is achieved by means for adjusting the gap between the Snail wall and the emptying table in its scope extent and / or in the vertical direction.  

Further developments of the invention are in the subclaims specified.

The invention is explained in more detail below with reference to FIGS. 1 to 9 of the drawing; it shows

Figure 1 is a schematic vertical sectional view of part of a rotary heating chamber furnace which is equipped with a screw.

Fig. 2 is a schematic plan view of the emptying table and the screw of Figure 1 in the plane II-II, including a pickup and an outlet for the emptying table.

Fig. 3 is an elevational view of the screw of Fig. 1, illustrating the size and width of the gap therein;

Figure 4 is a vertical section through the screw of Figure 3 taken along the plane IV-IV..;

Fig. 5 is a schematic elevational view of an execution form of a cylindrical screw after OF INVENTION dung with a vertically adjustable gap, starting from the screw according to FIGS. 3 and 4;

Fig. 6 is a schematic elevation view of another form of leadership from a cylindrical screw according to the invention with a circumferentially adjustable gap, also starting from the screw of Figures 3 and 4;

Fig. 7 is a schematic plan view of an emptying table, which is coaxial with the emptying shaft of a rotary heating furnace, and on an embodiment of a screw according to the invention, which is formed from individual components so that it has a gap adjustable width;

Fig. 8 is a screw, the gap increases uniformly around its circumference, but without showing the setting device for the gap; and

Fig. 9 is a schematic plan view of an emptying table, which is coaxial with the emptying shaft, in particular deep furnace, a rotary heating chamber furnace, and on a square screw.

Reference is first made to Fig. 1, which shows part of a sloping heating chamber 10 of a rotary heating chamber furnace, as has been generally described above. This heating chamber 10 is equipped with an agitator witness 11 , in particular an agitator hook, roasting scoops, scratches or the like. On the heating chamber 10 , which rotates about the axis 15 , an inverted frustoconical, ie downwardly tapering Ent drainage shaft 12 , in particular deep furnace, hangs in the middle. A circular rotary emptying table 13 is positioned under the emptying shaft 12 and rotates about the axis 14 , which is offset from the axis 15 of the rotary heating chamber furnace. As will be shown below, the screw proposed here can also be used in rotary heating chamber furnaces in which the heating chamber and the rotary emptying table rotate about the same axis.

A non-rotating frame 16 , which has a cover element 17 (cover, cover, cover or the like), surrounds the rotary discharge table 13 as well as the discharge end 18 of the discharge shaft 12 . The cover element 17 carries a peripheral depression or socket 19 , and the emptying element 18 of the emptying shaft 12 carries a downwardly extending or depending flange 20 which forms a seal with the peripheral depression or socket 19 . On the cover member 17 , a screw 21 is fixed so that it is coaxial with the Ent 12 chute. The cover element 17 may, for example, consist of a series of ribs.

As shown in Fig. 2, the rotary emptying table 13 is provided with a slide, gutter, chute or the like 22 and with a take-off 23 , which material, which has been unloaded by the screw 21 onto the rotary emptying table 13 , into the chute 22 deflects when the rotary emptying table 13 is rotated counterclockwise.

A screw, which is so complete in FIGS . 5 and 6 that there is an adjustability of the gap, is illustrated in elevation and in section in FIGS . 3 and 4. In particular, this screw has a cylin drical screw wall 26 which is formed with a flange 25 extending outwards, which is preferably circular before. A gap 27 is provided in the lower edge of the scroll wall 26, for example, be cut, molded, milled o. The like., And this gap 27 extends over a portion of the perimeter wall of the worm 26. In the present case, the circumferential extent of the gap 27 is referred to as its width. The vertical dimension of the gap 27 is referred to here as its depth. The upper edge 28 of the gap 27 in FIGS . 3 and 4 is parallel to the surface of the rotary emptying table 13 . The side edges 29 of the gap 27 may be vertical, or they may be inclined away from the upper edge 28 or be inclined in the sense of an expansion of the gap 27 after the rotary emptying table 13 .

FIG. 5 illustrates a screw which has a gap 56 which is adjustable in its vertical dimension (depth). The screw wall 55 has a circumferentially extending gap 56 , the upper part of which is covered by a plate 57 which is adapted to the screw wall 55 . According to FIG. 5, the lower edge 60 is held to the plate 57 at a level that is located above the lowermost edge of the scroll wall 55, so that the portion of the gap 56, which is the lowest between this edge and the lower edge 60 of the plate 57 remains unlocked. Vertically elongated slots 58 in the plate 57 take screws 59 , which are fastened in the screw wall 55 be. The plate 57 can thus be raised to the extent that is made possible by its slots 58 , and it is held in the raised position by means of nuts 61 which are screwed onto the screws 59 .

A worm with a circumferentially adjustable gap is illustrated in FIG. 6. The worm wall 62 has a lowermost edge 67 which is parallel to its upper edge 68 and extends around the main part of its periphery. The lower edge 63 of the smaller part of the screw wall 62 is raised relative to the edge 67 , so that a gap is formed between the edge 63 and the rotary emptying table 13 . A plate 64 is adapted to the curvature and the scroll wall 62 attached by a pair of screws 66 on the screw wall 62nd The screws 66 extend in a horizontal slot 65 through the screw wall 62 , so that the position of the plate 64 can be adjusted to change the effective circumferential extent (width) of the aforementioned gap.

In operation, a rotary heating chamber furnace, which is equipped with a screw according to FIG. 5 or 6, unloads its heated feed material into its emptying shaft 12 , from where the particles of the heated feed material fall into the screw and onto that part of the rotary emptying table 13 which currently falls below the snail is. The screw is axially movable for the purpose of positioning its gap and is adjusted so that the material or material to be loaded in the screw by means of the rotation of the rotary emptying table 13 is carried through the gap without problems. There must, of course, be play between the screw and the rotary discharge table 13 , and some fines can pass through this clearance, but most of the discharge takes place through the gap and therefore the discharge takes place as long as the rotary discharge table is at a constant speed rotates, with an appropriate constant volume rate (amount per unit of time), which is not greatly influenced by the particle size distribution. The unloaded material on the rotary emptying table 13 is guided into the chute 22 by means of the pick-up 23 .

A screw can comprise several structural units, in particular identical structural units. A modular screw, which is coaxial with its emptying table 49, is shown schematically in FIG. 7. The screw comprises a number of construction units 46 , each of which has an arcuate screw wall section 47 which forms part of the screw wall of a circular screw, and an arm 48 which extends from the respective screw wall section 47 to a holding device which extends beyond the scope of the rotary emptying table 49 is attached. The units 46 who, as shown in Fig. 7, so assembled, or -ge adds that the screw wall portions 47 are neighbors to each other or abut each other. By omitting one or more units 46 , a screw gap can be formed. Alternatively, the screw wall sections 47 can form a complete circle, but at least one of the screw sections 47 must have a gap or part of a gap in its lower edge. The screw shown in Fig. 7 enables a continuous adjustment of the gap width.

In Fig. 8, the specific part of a screw (without shown adjustment device) is illustrated, which has a gap which extends around its entire circumference, with a depth that increases uniformly over 360 ° from zero to its maximum value and then abruptly drops to zero. The screw wall 31 , if rolled into a flat strip, would have a width 32 at one end which is narrower than its width 33 at the other end and a lower edge 34 which is essentially a straight line.

The screw does not necessarily have to be circular in plan view, even if its circular configuration is preferred. Thus, the Fig. 9 shows a square screw 43, which is positioned coaxially with its rotary discharge table 44. The gap of the screw 43 can be in any wall. A non-circular screw can preferably have the shape of a polygon, particularly preferably that of a regular polygon.

Although the invention above in its application in rotary heating furnace, especially for burning, roasting, cal cinieren o. The like., It has also been described Ovens, in particular for burning, roasting, calcining o. Like., Applicable, in which the heating chamber stationary is and the stirring tools, in particular stirring hooks, roasting shovel, scratches or the like, with respect to the heating chamber rotate.

Claims (6)

1. Emptying control device for a rotary roaster, burner and / or calciner, the

• a heating chamber ( 10 ) with stirring tools ( 11 ), which preferably rotate relative to one another,
• - An emptying shaft ( 12 ), in particular a heat compensation shaft, which is attached centrally to the heating chamber ( 10 ) and extends downwards from it,
• - a rotary discharge table ( 13; 44; 49 ),
• - A non-rotating screw ( 21; 43; 46 to 48; 55 to 61; 62 to 68 ), the shaft between the emptying end ( 18 ) of the emptying shaft ( 12 ) and the rotary emptying table ( 13; 44; 49 ) is attached, and the has at least one gap ( 27; 56 ) between its screw wall ( 26; 47; 55; 62 ) and the rotary discharge table ( 13; 44; 49 ), through which the material coming from the discharge shaft ( 12 ) passes over the screw ( 21 ; 43; 46 to 48; 55 to 61; 62 to 68 ) flows out onto the rotary discharge table ( 13; 44; 49 ),

characterized by
a device ( 47; 48; 64 to 66 ) for adjusting the gap between the screw wall ( 47; 62 ) and the rotary discharge table ( 13; 44; 49 ) in its circumferential extent and / or
means ( 57 to 59; 61 ) for adjusting the gap ( 56 ) between the screw wall ( 55 ) and the rotary discharge table ( 13; 44; 49 ) in the vertical direction. 2. Device according to claim 1, characterized in that the gap ( 56 ) remains substantially the same in the circumferential direction. 3. Device according to claim 1, characterized records that the gap evenly over at least part of its size increases. 4. Device according to claim 1, characterized in that the screw ( 46 to 48 ) comprises a plurality of construction units ( 46 ), each of which a portion ( 47 ) of the peripheral wall of the screw ( 46 to 48 ) and an arm ( 48 ) has to be attached to a holding device in such a way that a worm ( 46 to 48 ) with a predetermined adjustable circumferential extent of a gap or several gaps can be joined together. 5. Device according to one of claims 1 to 4, characterized in that the screw ( 43 ) is polygonal in plan view.