DE238739C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

CLASS Ma. GROUP

Dr. PAUL PICCARD in GENEVA.

Evaporation kettles, which are used to evaporate saturated salt solutions Used to produce salt crystals, consist mainly of a vessel, which the ' contains solution to be evaporated, and a means immersed in this liquid Steam heated radiator.

The solution in these evaporation kettles does not remain calm because that of

ίο The liquid touched on the heating surfaces expands and strives upwards, while the liquid that has remained cold goes downwards, occupying the space of the ascending one. So a continuous circulation is formed, which is still due to the formation of vapor bubbles, which arise where the liquid is hottest, is accelerated.

The circulation is more or more, depending on the arrangement of the boiler and the shape of the radiator less violent.

As the dissolvability of almost all bodies increases with increasing temperature, it follows that also the degree of saturation of the solution differs considerably from one point of the circulation to another.

It is where the liquid is warmed up without the formation of steam unsaturated or dissolving, whereas they are saturated, often even oversaturated in the places is where steam forms without being heated, because that is where the dissolved body becomes more solid Form.

Solid deposits form in such places, often on the walls of the apparatus adhere, while the liquid unsaturated in other places is even more solid could dissolve if she found one on her run.

The deposits adhering to certain places cause blockages, which paralyze the operation of the apparatus in a short time.

The purpose of the present invention is to prevent such clogging.

It consists in the peculiar arrangement of the evaporation vessel, which serves to first: automatic circulation through the heating and evaporation of the salt solution to effect a closed circuit; second: the direction of this circulation Reverse from time to time to avoid those points where the debris is at in a direction of rotation, after reversing the direction they are exactly where the liquid has a dissolving effect.

It is true that the deposits formed at one point are dissolved in other places again, but these will be with the next reversal dissolved by the circulation, so that the apparatus remains free from clogging, whereby a continuous operation is achieved will.

The accompanying drawing shows, for example, two arrangements of such evaporation kettles with reversible circulation, thereby fulfilling the purpose described above. Both Boilers are symmetrical with respect to the vertical central axis.

In Fig. Ι A is the outer container of the evaporation boiler, B the radiator, which can be any system and here

is shown as a standing tubular boiler. This radiator B is covered with a hood C , which is provided with two externally movable flaps D and E. F is the heating steam supply pipe. G the condensate drainage pipe and I the drainage port for the steam escaping from the solution. H is a vertical partition dividing the boiler A into two halves, the upper one

ίο The edge, however, is still below the liquid level. / and K are chambers in which the solid matter, ζ. B. Salt, is deposited on the bottom of the boiler A.

As soon as the heating steam is introduced through the pipe F into the radiator B , after the flap D is opened and E is closed, there is a circulation in the direction of the arrow, according to FIG. 1 left upwards and right downwards.

When the circulation has started, flap D is closed and E is also closed; however, the circulation continues because the liquid in the left half is hotter than that of the right.

As long as the circulation exists in this sense, the solution which enters the heating tubes of the right half of the radiator B from below is oversaturated and forms deposits that adhere to these tubes and gradually clog them. However, as soon as this blockage has a disruptive effect, you change the direction of the circulation by opening the flap E on the right; then the hot liquid of the hood C rises into the right half, contrary to the existing circulation, and reverses it.

After the new circulation has started completely in the opposite direction of the arrow, flap E is closed again and both flaps are left closed. As a result of the new direction of circulation, the deposits that have just formed are dissolved because the solution which has flowed through the heating element B , which is very hot and desaturated, flows from top to bottom through the tubes in the right half.

New deposits will form in the tubes of the left half, the however, after repeated reversal of the circulation, loosen, etc.

Since it is desirable that the liquid which is to loosen the deposits, the has the highest dissolving power, any vapor formation during the heating of the Liquid should be avoided because this vapor formation increases saturation would result.

This is achieved by placing the radiator so deep in the liquid to be evaporated built in that the hydraulic pressure is greater than the heating steam voltage corresponding to the temperature. That way Steam can only bubble when the hot liquid rises, i.e. above it of the radiator.

Since the solid body separates from the water where it is transformed into vapor, this solid body will only be formed in the ascending column of liquid and from there carried away by the vortex of the circulation, which forms a closed circuit, into the descending column of water, finally in the chamber K, where the water is relatively calm, to get and settle. From here the solid material, e.g. B. salt, scooped out by any of the known conventional methods.

In Fig. 2, as a second example, there is an evaporation kettle of a slightly different form from the previous one, but the operation is the same.

The two upper halves of the boiler A (Fig. 1) are replaced by the two outer tubes A and A ¹ (Fig. 2), which unite in the dome L , from which the steam escapes through the nozzle J.

The mode of operation shown in FIG. 2 is identical to that in FIG. 1 and is understood without further explanation by the similarity of the letters.

Instead of the single radiator A, it would also be possible to set up two separate, symmetrical radiators which would be connected at the top by a communication pipe which replaces the hood C in FIGS.

Furthermore, the reversal of the closed circuit-forming circulation could be accomplished by other means than by the flaps D and E. B. for the same purpose use a steam jet, which would be directed in the sense of the respective circulation to be achieved in the liquid, or also, using the mechanical action, immerse a kind of piston in the liquid, which you move in the direction of the circulation to be formed would. All of these means for the temporary formation of the circulation are secondary to the invention, since the end sought can be achieved with all of them.

The present process is aimed solely at elimination or production of salt crystals from a saturated salt solution, with constant dissolution the deposits of salts adhering to certain points of the evaporation apparatus.

Both the circulation of the treated solution and its reversal take place inside one and the same cauldron, where the former is self-contained Cycle forms.

Finally it should be noted that the circulation in the present process is not mechanical Devices is generated, but is automatically conditioned by the heating of the apparatus.

Claims (1)

Patent claim: Process for the production of salt crystals from a saturated salt solution, ίο characterized in that in one with The solution to be evaporated is provided by an upright radiator and consists of two communicating halves now in one direction, now in the other, automatically through the two halves of the apparatus circulates in a closed circuit to remove the deposits of salts, which at certain points of the evaporator adhere to permanently remove. 1 sheet of drawings.