DE261210C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JVl 261210 - CLASS 12 /. GROUP

EMIL THIE in CHARLOTTENBURG.

of potash salts and the like.

Patented in the German Empire on October 18, 1911.

In the potash industry, efforts have been made for a long time to use the previous dissolving boiler continuously to replace working devices, such as loosening screws or loosening drums.

The facilities of this type that have become known so far show, in addition to other shortcomings, like complicated construction etc., the great disadvantage that the resolution is imperfect precipitates as soon as the salt to be dissolved

ίο not a specific composition and Has texture.

The present invention now aims to provide the individual apparatus for each solute in to make the same measure suitable and achieved this by regulating the speed of passage of the solute according to the for its dissolution required time, with the dissolving liquid all the way in same or opposite or on the first part of their way in the same and on the second part of the path flows in the opposite direction.

In this way, a wide variety of crude salts, like Carnallite, Hartsalze, Sylvinite in the same apparatus with equally good results decomposed or dissolved, as well as the proportion of secondary salts and impurities as well as their intergrowth, and also manufactured products such as potassium chloride etc., are covered. The throughput speed of the material is regulated without interrupting the movement of the agitator mechanism by adjusting the transport members, according to which the transporting one The effect of the latter increased, decreased, abolished or periodically reversed (Return transport) will.

FIGS. 1, 2 and 6 of the drawing show a plurality of drums set up to carry out the new method in a configuration only by way of example. 3, 4 and 5 show cross sections along line AA or BB and CC of FIG. 2, FIGS. 7, 8 and 9 likewise along line DD or EE and FF.

α is a sheet metal drum lying on rollers, which is constantly rotated by a wheel gear engaging in a toothed ring b of the drum shell. The raw salt to be dissolved is fed in at one end of the drum by means of a chute c, the insoluble residues are ejected at the other end of the drum by means of a perforated lifting cup d sitting on the inner drum wall and a stationary chute e ; instead of the chutes c and e , augers can also be used. The dissolving liquid is introduced at the same end of the drum as the salt or, better, as shown, at the opposite end and then leaves the drum at the salt inlet end.

The swirling of the salt in the liquid takes place in a known manner by solid-walled or perforated lifting blades / which the salt from the dissolving liquid in the top

Lift the drum chamber and then fall back into the solvent below permit.

According to the present invention, a number of inclined to the shaft are now in the drum space on a rotatable shaft g

. of disks i, 2, 3, 4, 5. . . arranged, whose Position to the vertical can be changed by rotating the shaft in such a way that the Discs (see disc 3 in Fig. 1) greater or lesser inclination - to the left (position 3) or incline to the right (dotted position3 ') or stand vertically. In the former In the second position, the panes move forward, in the second position they move back, and in the third (middle position) you avoid forward and backward transport. .

In the embodiment according to Fig. 1, the transport disks are all seated obliquely on the shaft in the same direction (parallel arrangement) and, when the shaft is adjusted on the handwheel η according to the amount of adjustment, all of them accelerate or retard the speed of passage of the salt in the same sense . A small handle, which can be carried out while the drum is rotating, is sufficient to reduce the speed at which the material to be dissolved passes through and to improve the yield if the residue ejected by the apparatus still contains soluble parts. In the embodiment according to FIG. 2, the transport disks sit alternately on the shaft with right and left inclination, and the salt transported by one disk is prevented from further passage through the drum by the following disk until the direction of inclination is achieved by rotating the shaft by 180 ° of the discs is reversed to the perpendicular. If the disk shaft is in the position shown in FIG. 2, the amount of salt falling on disk 1 slides forward a little. The salt is immediately lifted again by the lifting shovels / the rotating drum and, after some accumulation, falls onto the next disc 2, but the latter leads it back to where disc 1 had transported it.

If the shaft is now rotated by 180 °, disk 1 assumes the dotted position 1 'and disk 2 assumes the dotted position 2'. Disk 1 now holds the following salt., While disk 2 lets the salt previously transported by disk 1 slide forward a further distance. The salt gets into position at the moment. 3 'located disk 3, in front of which it accumulates until disk 3, according to him, allows a further rotation of the shaft by 180 ° to slide forward towards disk 4. This game takes place over the entire length of the drum and offers a means of arranging the passage of the salt through the drum so that at the end of the drum, by appropriately dimensioning the switching periods, which are to be kept longer for sparingly soluble salts and shorter for easily soluble salts only the insoluble residue arrives, which is discharged in a known manner through perforated lifting cups d and a chute e or the like.

The periodic changeover of the transport plates takes place automatically by a release disc m with two diametrically located pins on its support shaft g , which drive the worm wheel 0 from an uninterrupted rotating disc with removable drive pins with the help of a clutch located in the drive after each rotation disengage the shaft g by 180 °, while the headstock pulley causes the clutch to be engaged at shorter or longer intervals, depending on the number of driving pins left in it.

So that the salt pushed forward by a transport disk does not partially slide back on the same disk when the next half turn of the shaft causes the disk to reverse its inclination, and also to avoid exhaust steam, exhaust gases from furnaces, heated air or a To force other heating means into the drop space of the salt and the dissolving liquid, it is advantageous to use an annular sheet metal wall i immediately in front of each disk (FIGS. 2 and 6). For the latter reason, the transport disks are alternately shortened at the top and bottom by a segment of a circle so that they have the shape of a shield, as shown in FIGS. 3 and 4. As a result, the hot gases take a serpentine shape between the transport discs. Path (arrow s) and are thereby brought into intimate contact with the material, which always falls in large quantities during the rotation of the drum, whereby they provide an increased replacement for the heat of the dissolving liquid consumed by the dissolving process.

The annular plates i can also be used, by appropriate height measurement, to gradually mix the inflowing, thin dissolving liquid with the outflowing, concentrated lye in a known manner. impede. . .-.

t are externally adjustable lifting and transport shovels, which distribute the loosening material that has accumulated in front of the inlet chute or auger c and regulate the throwing of the same onto the first sliding plate 1.

In the representations in Fig. 1 and 2, the liquor is ger in countercurrent to the crude salt

leads. In the case of crude salts, which, as a result of the previous grinding, also includes fine salt particles contained loosely or clear or through immediately upon falling into the solvent eye form partial solution, the disadvantage occurs here that the lye removes the fine salt parts discharges undissolved, which then precipitate in the clarification basins. To now also the fine Dissolving salt particles becomes the solution

ίο of the crude salt initially in cocurrent and then only carried out in countercurrent.

In the embodiment according to FIG. 6, dissolving liquid occurs at both ends of the dissolving drum, and both liquor streams move towards the center of the drum, where they pass through an interruption u in the drum shell into a drum af of slightly larger diameter surrounding the actual dissolving drum α and into flow from the space between the two drums to the end faces in order to leave the release apparatus there in a known manner.

This facility is particularly necessary when processing raw salts rich in carnallite. The salt that falls into the solution contains, as a result of the previous grinding, "partly also fine potassium chloride, sodium chloride, Chlorine magnesium and kieserite; furthermore, the magnesium chloride dissolves very quickly from the carnallite with the separation of fine potassium chloride, the latter due to the movement taking place in the dissolving apparatus keeps itself floating and with exclusive guidance of the dissolving liquid in countercurrent undissolved by the alkali emerging immediately behind the point where the crude salt fell is washed away.

Claims (6)

Patent Claims: I. Process for the continuous decomposition, dissolution and covering of potash salts and other products in rotating drums, characterized in that the progressive movement of the Soluble matter in the drum in the ratio of its solubility by regardless of Drum rotation occurring change in the angular position of the transporting organs increased or decreased. 2. Drum for carrying out the method according to claim 1, characterized by a shaft (g) rotatable independently of it with transport disks (1, 2, 3, 4, 5...), Whose " Inclination to the direction of fall of the loosened material lifted in a known manner by lifting shovels (f) of the rotating drum shell can be changed by hand or automatically at intervals of adjustable duration and vice versa. 3. Drum for carrying out the method according to claim 1, characterized in that that the sliding plates are alternately shortened on the opposite side by a segment of a circle to form a shield are to exhaust steam, fire gases, heated air and the like guided through the drum by serpentine guides to bring them into longer and more intimate contact with the falling solids. 4. drum for carrying out the method according to claim 1 ,. characterized in that ring-shaped walls (i) are inserted into the drum in such a way that goods transported forward by a transport plate cannot be transported back again from the same transport plate after the transport plate shaft (g) has been switched over. 5. Drum for carrying out the method according to claim 1, characterized in that that by arranging one lye inflow at the two drum ends and one lye outflow at one middle point the solution is carried out first in cocurrent and then in countercurrent to the dissolving solution. 6. Drum for carrying out the method according to claim 1, characterized in that the actual release drum (a) is surrounded by a second drum (α ', Fig. 6 to 9) connected to it, around the solution emerging from the former at the middle point take up and to lead to the end faces of the drum, where the solution leaves the drum in a known manner. '. . For this purpose 2 sheets of drawings,