DE297869C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 297869 CLASS 85 b. GROUP

in Munich.

the resulting solution.

Patented in the German Empire on September 22, 1916.

A number of the most varied facilities are known, solutions in a particular one automatically allocate percentage ratio to the liquids to be prepared. .

The largest number of these facilities, however, suffer from the fact that in practical continuous operation the mode of action leaves something to be desired, so that the amounts of liquid to be prepared either too little or too much or at times not at all with the corresponding Solutions are offset. Attempts have been made to place metering pumps in a relationship of dependency to that funding facility, ζ. B. centrifugal pumps and the like, too bring which z. B. promotes an amount of wastewater. However, this type of pump is strong at changing levels of resistance and tour fluctuations make significant changes in the subject to hourly delivery rate in which the dosing pump does not participate, so that an equivalent ratio of the dosage amount to the main liquid amount set once can never be sustained.

Naturally, this not only results in a considerable waste of chemicals, but also the desired effect is achieved even in the rarest of cases. More difficulties still exist in the fact that these known facilities in protected rooms for installation have to reach, whereby under certain circumstances very long pipelines for the generated Solution to lead the latter to where it is needed. However, all of these lines are laid in a very short time by crystallizing the dissolved ones Salts, which in turn cause significant operational disruptions.

The essence of the present innovation consists in all machine facilities switch off and only dissolve as much chemicals and release solution at a time, as much is necessary to achieve the desired effect, namely in the Way that all processes depend on a respective amount of liquid flowing through which is to be prepared, and the work processes by lowering the liquid level take place.

The attached drawing is a device shown for the execution of the procedure:

ι is a control chamber in which the wastewater to be prepared flows through the float valve 2 occurs and when the valve 2 closes it assumes a certain level. 3 is Another chamber in which the dissolving tank 4 for the chemicals to be dissolved is located is located. The same has under the grate 5 a close to the casing 4 Funnel 6, from which a pipe 7 leads to close to the bottom of the container 4. Outside of of the jacket 4 is a further annular jacket 8, the upper edge of which is around protrudes a certain amount over the grate 5. The one formed by the jacket 4 and jacket 8 annular space stands through the

Openings 9 in communication with the lower part of the container 4. Around the jacket 8 is located Another jacket 10, the upper edge of which protrudes slightly beyond the edge of the jacket 8 and is covered by a lid 11 provided with openings. The jacket 10 has at the lower part on the inside standing sheets 12, around the at 13 through the measuring nozzle 14 to instruct the amount of liquid entering a zigzag path, which then at 15 (Fig. 2) exit. A larger pipeline 16 leads from the control chamber 1 to the measuring nozzle 14 and a smaller pipe 17 into the interior of the dissolving tank 4. In this pipe 17 there is a nozzle 18 adjustable by means of a displaceable core, around the flowing through To be able to regulate the amount of solvent liquid with the help of a handwheel.

The whole system in chamber 3 is under water, and chamber 3 is also under water in connection through the drainage slot 19 with the clarifier 20 or the like. Through the pipe 16 and the inner cavity of the jacket 10 is the control chamber 1 in communicating Connection with chamber 3 and clarification basin 20. Now finds a water outlet instead of from the clarifier 20, the level of the level in the same sinks, and due to the difference in the level of the level in the container 20 and a main amount of liquid corresponding to the nozzle cross section 14 flows in the control chamber r to the interior of the jacket 10, the outlet 15, Fig. 2, the chamber 3 and from here through the overflow protection after the clarification tank 20. At the same time, an amount of water of solution corresponding to the nozzle cross-section 18 flows into the interior of the jacket 4. At On its way through the chemical crystals in the grate 5, it dissolves the latter and sinks through the funnel 6 and the pipe 7 to the bottom of the dissolving container 4. Here the solution passes through the opening 9 to the annular space of the shell 8 and from since over the edge to the annular space formed by the jacket 10 after down between the mixing plates 12 and mixes there with the main amount of liquid, with which it then exits jointly at 15 in chamber 3. The flow rates the two tubes 16 and 17 are in one, their cross-sections corresponding definite, permanent ratio, so that in this way the percentage of solution amount formed always remains the same, regardless of whether the incoming amount of liquid is large or small.

The addition of the amount of solution is regulated completely automatically from the water withdrawal from the clarification tank 20 resulting mirror height difference between the clarification tank 20 and the control tank 1. Heard the water being drawn from the clarification tank 20 stops, so also stops after equalization of the mirror height in the control container 1 in the chamber 3 and in the clarification tank 20 the inflow of the solution. Of those located in the dissolving tank 4 Chemicals are only dissolved as much as the amount of solution water contained or flowing in able to absorb, whereupon the solution process comes to a standstill, until the lowering of the level of the chamber 3 an outflow thereof in proportion to the inflow of solution water through the nozzle 18 takes place. The solution water arriving through the nozzle 18 is not immediately a concentrated one Tried solution result in the first passage through the chemical crystals. That located in the dissolving cylinder 4 tube 7 is at a certain height from the bottom of the Container 4 from.

If fresh water of solution now arrives at the top, the opening 9 is initially the displaced finished, specifically heavier solution. The lighter solution rises outside the pipe 7 again in the annular gap formed between the funnel space 6 and the container jacket 4 high, where it is again saturated with chemicals and after reaching a certain, the weight corresponding to the percentage of the dissolved substances, through the pipe 7 sinks again until it is complete Saturation. '

Claims (8)

Patent Claims: 1. Process for the automatic dissolution of solid chemicals and for quantitative Allocation of the resulting solution to any amount of liquid, thereby characterized in that the respective equivalent resolution and allocation by Difference in height of the water level of two communicating Containers (1 and 3) takes place. 2. The method according to claim 1, characterized in that the equivalent ratio the amount of solution to the amount of liquid to be dosed through two calibrated nozzles (14 and 18) of a specific cross-section takes place, of which one (18) for the solution water amount can be regulated in this way is that the outflow coefficient remains constant with changes in cross-section. 3. The method according to claim 1, characterized in that by the in one Dissolving container (4) arranged grate (5) with funnel (6) and pipe (7) a continuous Circulation of the amount of solution up to complete saturation takes place in such a way that that caused by saturation is specific heavier solution sinks down through the pipe (7), with the less saturated amount of liquid outside the pipe (7) is pushed up after the chemical supply. 4. Embodiment of the method according to claim i, characterized in that two communicating chambers for the quantitative addition (1 and 3), in which there is a float valve (in chamber 1) and (in chamber 3) the disintegration and distribution device is located, where (in chamber 3) the mixing of the solution with the main amount of liquid takes place at the same time. 5. Embodiment of the method according to claim 2, characterized in that the quantitative allocation or the equivalent ratio of the solution to the main ■■ amount of liquid through two calibrated nozzle nozzles (14 and 18) takes place, of which the one for solution water (18) is adjustable in such a way that the outflow coefficient through one of the nozzle shape corresponding, movable core remains constant when changing the 'free cross-section. 6. Embodiment of the method according to claim 3, characterized in that the dissolution of the chemicals takes place in a container (4) in which a Grate (5) with the funnel (6), the incidence tube (7) is located, with the finished solution through the openings (9) to the annular space of the container jacket (8) can kick. 7. embodiment of the method according to claim 3, characterized in that the solution, which passes over the edge of the jacket (8), through another Jacket (10) is passed downwards and there within vertical sheets (12) through the zigzag formed for the water flow with the main amount of liquid is intimately mixed. 8. Embodiment of the method according to claims 1 to 7, characterized in that that the entry of the main amount of liquid into the dissolving tank (4) takes place tangentially. 1 sheet of drawings.