DE1542374C - Device for heat and / or mass transfer between finely divided solids and a gaseous medium - Google Patents

Description

The invention uses the knowledge that im

single concentric Feststoffsammeiräume upstream i ₀ central portion of the screw from the gases

are seen, which at its upper end via an inlet opening with the shaft interior and on their lower end in connection with a deeper part of the shaft interior via discharge pipes stand, ■

. For heat and / or material exchange between one-part solids and a gaseous medium a device is already known which essentially consists of a vertical shaft,

substances are only used in the inner subspace led downwards, while the gaseous medium partly in the inner subspace and partly in the outer

In the interior of the manhole with a linear flow, there is a certain negative pressure (vertebral depression). If the discharge pipes of the solids collection spaces open out in this central area of the shaft interior 15, it is therefore possible to dispense with any material locks, such as movable pendulum flaps, in these discharge pipes; with regard to the pressure conditions, the herriind one hand to the mouth of the discharge pipes and on the other hand, at the entry whose inner space through a pipe ₂₀ into an inner opening of the associated Feststoffsammeiraumes an outer part space is divided. The festivals see, the gases take their way anyway

the shaft interior. The elimination of the material locks in the individual discharge pipes simplifies the construction and reduces the required sub-space flows upwards. · Due to the maintenance carried out on this 35 as well as the susceptibility of the Way created for the gas flow by the way (in the appendix.

outer subspace) .should be the gas in the inner subspace.

speed are reduced so that _we ise for preheating, baking and / or cooling the finest components of the solids movement _from cement raw meal, lime, dolomite, magnesite, gen. to The main drawback of these known advantages other 30 ores, alumina hydrate and fine-grained richtung.liegt in the very different dwell _o d _e r dustlike solids are used.

It can also lead to an exchange of substances by way of some chemical reactions between the solids and the gaseous medium are used.

Some embodiments of the invention are illustrated in the drawing. It shows

F i g. 1 shows a vertical section through a device according to the invention according to a first embodiment are. In this preliminary example, the solids are

direction of the helical in the shaft Fig..2 a section along the line IMI of the

The rising gas flow is periodically discharged from the shaft, collected in the aforementioned solids collection spaces and via the discharge pipes

these spaces in a deeper part of the shaft 45 Fig. 4 is a vertical section through the upper re-registered interior. You can refer to this part of a second embodiment of the invention

time of solids of different grain sizes in the shaft and thus in insufficient heat and / or substance exchange with the coarse-grained components.

To improve warmth and / or warmth one has continued to develop devices of the type mentioned, in which on SchachUimfang individual solids collection rooms

Fi g. 1,

F i g. 3 shows a partial section along the line III-III of Fig. 2,

Way to work with relatively high gas velocities in the shaft and still ensure a gradual countercurrent movement of the solids downwards.

In a device of the last-mentioned type, care must be taken that the in the shaft ascending gases do not find their way through the earth,

5 shows a perspective schematic illustration of a further exemplary embodiment.
50 The device according to FIG. 1 contains a shaft 1, which is divided into four superimposed stages la, Ib, Ic and Id . The stages la, Ib ■ undTc are "designed to be substantially homogeneous, mentioned discharge pipes of _{Feststoffsammeiräume;} They contain _jevveils:... To take an upper cylindrical since they in this case the downward movement of the _'55 part 2, an adjoining, downwardly" expanded Solvents would get in the way of these pipes. In ternden conical part 3 and a lower part 4, the known apparatus are for this purpose in the concentric j _n at chess turn catch ^ four Festden Auslrugrohrcn material locks, for example, material collecting chambers 5 are provided.
Pendulum flap)! provided, which a downward bcwe These solid sums 5 are at their

allow the solids to flow an upwardly 60 upper end via an inlet opening 5 a mit'dem directed gas flow in these pipes, on the other hand, communicating the shaft interior while at prevent. In view of the relatively high the lower end of each solids collection space 5 a Temperatures, which these movable locking members discharge pipe 6 connects, the oblique downward to are exposed to considerable wear and tear towards the shaft axis in a freely continuous connection and a strong susceptibility to interference inevitable. 65 (i.e. without material locks) and in The invention is therefore based on the object of the central area of the shaft interior in the a device of the type mentioned at the beginning opens out from the next deeper shaft step. At this / ubbildung that on the mentioned, wear and embodiment, the mouths of the to one

Level belonging discharge pipes 6 each in one level.

As in particular F i g. 2 can be seen, the inlet openings 5 a of the four solids collection spaces of each shaft step complement each other to form a closed annular slot. The solids collection spaces 5 narrow from the inlet slot 5 a to the attachment point of the associated discharge pipe 6 in the manner of a funnel (see FIG. 3). The Feststoffsammeiräume 5 of a bay level with ^their: inlet openings 5a and its discharge pipes 6 are symmetrically distributed around the shaft axis (see F ig. 2.).

The cylindrical inner boundary wall 7 of the lower part of a shaft step (z. B. Ib) forming solids collection spaces 5 has approximately the same diameter as the upper part 2 of the shaft step, while the middle one, which forms the transition between the upper and lower part of a shaft step Part. 3 conically expanded to the outer diameter of the solids collecting chamber 5.

In the embodiment according to FIG. 1 opens approximately in the middle area tangentially between) two shaft stages Ib and Ic into the shaft interior a fuel supply line 8, through which a fan 9 and a fuel feed 10 primary air and fuel are introduced into the combustion zone of the shaft; At the lower end of the shaft a supply line 11 is provided through which the cooling air, which at the same time forms the secondary air for the combustion zone, is introduced tangentially into the shaft interior.

Two cyclones 12 and 13 are connected to the upper end of the shaft, the discharge pipes 12a and 13a of which are combined with the discharge pipes 6 of two opposing solids collection spaces 5 of the uppermost shaft stage which open into the second shaft stage Ib. A solids inlet pipe 14 opens centrally into the uppermost shaft stage la. The gas feed lines 12 b and 136 to the cyclones 12 and 13 are connected tangentially to the upper part of the shaft stage la.

The device shown in Figs

serves to remove fine-grained or dusty solids to preheat one after the other in shaft 1 to burn

) and to cool. The mode of action is as follows:

The gaseous medium (formed by the cooling air supplied through the supply line 11 and the fuel gases supplied through the supply line 8) flows through the shaft 1 approximately helically from the bottom to the top (flow path 15) and is discharged via the cyclones 12 and 13. The material to be burned • enters through the entry pipe 14, is carried outward by the centrifugal effect exerted by the helical gas flow and slides along the inner wall of the cylindrical part 2 and the conical part 3 of the uppermost shaft step on the circumference of the lower part 4 of the solids collection rooms at the top of the shaft. From this it then passes through the discharge pipes 6 in the central region of the following stage chute 1 b a. Here, the solids again come into intensive contact with the gas, along the flow path 16 shown in dashed lines are about carried a piece with upwardly pulled outwardly again and then pass via the Feststoffsammeiräume 5 and the discharge pipes 6 of the shaft step 1 b in the central portion the following shaft stage 1 c etc. The solids finally emerge through a discharge opening 17 at the lower end of the shaft.

The solids are thus introduced into the core of the gas flow in each individual shaft stage and whirled through intensely, the heat transfer between the solids and the gas in the individual shaft levels are carried out according to the cross-flow principle. Based on the whole shaft the solids move in countercurrent

ίο gas.

In the illustrated embodiment, the solids are essentially preheated in the two upper shaft stages la and Ib by the rising fuel gases; The solids are burned in the zone between the shaft stages Ib and Ic and cooled by the cooling air in the lower shaft stages Ic and Id , which at the same time results in the desired preheating of the secondary air for the combustion zone. '

No locks are required in the discharge pipes 6 of the individual solids collection spaces 5, since there is no risk of the gas flowing through the collection spaces 5 in view of the pressure conditions present at the inlet opening 5 a of a collecting space 5 and at the mouth of the associated discharge pipe 6 flows at the top and "thereby hinders the downward movement of the solids in the discharge pipes. ■" ₍

While in the illustrated embodiment, the solids are preheated in a single shaft, To be fired and cooled, it goes without saying that the device is only used for one of these purposes use. In the case of a pure preheater, hot gas is fed tangentially to the shaft at the lower end, which moves upwards in a helical manner through the gradual intensive Contact with the solids increasingly cools down, while those at the upper end of the shaft are cold Heat solids accordingly. at

Using the device as a cooler, cold cooling air is supplied to the lower end of the shaft while the solids are added hot on top.

In the further embodiment shown in FIG are at the top of the shaft 1

two cyclones 12 and 13 are also provided. Your discharge pipes 12 a and 13 a open in this embodiment in the central area of the uppermost shaft step la. The feeding of the solids takes place here via an entry pipe 18, which in

a gas line leading from the upper end of the shaft to the cyclones 12 and 13 opens.

In this exemplary embodiment, the solids discharged via the inlet pipe 18 are removed from the ' through the gas line 19 gas flowing into the

Cyclones 12 and 13 out, deposited there and then pass through the discharge pipes 12 a and 13 a in the top shaft stage la. This is where the solids get swirled outward in the manner explained and via the collecting spaces 5 of the uppermost shaft level la fed to the following shaft levels.

In Fig. 5, finally, a further embodiment is illustrated in schematic form, in which the shaft is not divided into individual, clearly separated stages, but

in which the Feststöffsammeläume 5 'with their entry slots 5'a and their discharge pipes 6 'are arranged in a spiral around the shaft axis. the Spacing of the continuously

Lined up solids collection rooms and discharge pipes can be chosen arbitrarily within wide limits. The mode of action of this arrangement corresponds basically that of the previously explained exemplary embodiments.

Claims (6)

Patent claims: 1. Device for heat and / or mass transfer between finely divided solids and a gaseous medium, in particular for preheating, burning and / or cooling the solids, consisting of a multi-stage shaft with tangential gas supply at the lower end, Solids supply kn upper area, solids discharge at the bottom and tangential gas discharge at the upper end, with individual concentric solids collection spaces being provided on the shaft circumference are that at their upper end via an inlet opening with the shaft interior and at its lower end via discharge pipes with a deeper part of the shaft interior in Are connected, characterized in that the discharge pipes (6, 6 ') in free open through a continuous connection in the central area of the shaft interior. 2. Apparatus according to claim 1, characterized in that the mouths of the to one Level associated discharge pipes (6) each lie in one plane. 3. Apparatus according to claim 1, characterized in that the solids collection spaces (5 ') with their inlet slots (5'a) and discharge pipes (6') are arranged in a spiral around the shaft axis. 4. Apparatus according to claim 1, characterized in that the solids collection spaces (5) from the inlet slot (5 a) to the attachment point of the associated application pipe (6) like a funnel narrow. 5. Apparatus according to claim 1, characterized in that the cylindrical inner boundary wall (7) the solids collecting spaces forming the lower part (4) of a shaft step (e.g. la) (5) has the same diameter as the upper part (2) of the shaft step, and that the middle, which forms the transition between the upper and lower part of a shaft step Part (3) widened conically to the outer diameter of the solids collection space. 6. The device according to claim 1 for successive preheating, burning and cooling of the solids in the shaft, characterized in that a fuel supply line (8) opens tangentially into the shaft interior approximately in the middle region between two shaft stages (e.g. Ib, Ic). 1 sheet of drawings