DE437483C - Device for the action of gases on liquids or of gases on a mixture of liquids and solids - Google Patents

Description

Device for the action of gases on liquids or gases on a mixture of liquids and solids. Bodies.

When working with the multi-tower reaction vessel described in the 402509 patent was used in the preparation of copper oxychloride and similar heavy metal compounds at a certain point in the reaction the entire contents of the air charged Tower is emitted in such a way that the emulsion overflows over the upper edge entered.

It has now been found that this deficiency can be avoided in a simple manner can be, if you put the two reaction towers above through an airtight U-shaped tube of approximately the same diameter connects the towers and at the same time the two cross-connections of the "towers" also approximately correspond to the cross-section of the Response towers expanded. This results in a significantly accelerated circulation of the liquid and also the surface in the second tower for de-emulsion made usable.

The exposure time of the gas to the liquid mixture is opposite the known facilities extended significantly by the reaction mass over the entire tower cross-section is emitted and the entire liquid layer of the two towers can circulate completely unhindered, without being tapered by cross-sections to be disabled. The gas-tight seal achieved by the airtight tube the system also allows the compressed gas to exit under pressure let or several systems combined one after the other to form a column with one and systematically process the same gas flow until it is used. The saturation the liquid is completed in a considerably shorter time, or with the same reaction mass a considerably smaller apparatus is required for the same performance.

In the systematic way of working, by arranging Circulation devices pass the liquid through all systems in sequence and the gas flow against the flow of the liquid according to the countercurrent principle let flow through all tower systems. The multi-tower reaction vessels are directly or indirectly heated or cooled from outside or inside as required. the individual tower parts are where there is a solid body as a reaction product separates, equipped with a device for more convenient emptying of the finished product.

In Figs. A, B, C the direction of flow of the gas is indicated by arrows without and the direction of flow of the liquid indicated by arrows with feathers. The figures are only shown schematically, and the height of the towers in proportion its diameter can of course be designed as desired. In fig. A, the two towers are labeled I and 2, respectively, and they stand through the connecting tubes 3 and 4 in their upper and lower parts in connection with each other. The upper Part of the towers is designed as a communicating tube 5, the lower parts of the Towers have funnel-shaped attachments 6 and for possible emptying of solid products 7, which are completed by evacuation slide 8 and 9. Io are water levels to observe the liquid level inside the systems. ii are pressure gauges for Pressure reading. The gases pass through the pipe I2, I3 and gas manifold 14 into the Liquid one.

They emulsify the liquid in the tower part I, making that easier specific weight of the contents of the tower. in 1, which is consequently due to the heavier of the tower 2 is pushed up.

The emulsified liquid rises according to the direction of the arrow and flows through cross connection 3 and the pipe part 5 in the tower 2 i over, its The liquid level has decreased accordingly. After the air has escaped in the Tower part 2 sinks the liquid which has become heavy again after the demulsification down in an uninterrupted cycle. The worked out gases pass through the stopcock 15 off.

For better distribution of the gases within the liquid is the gas inlet pipe in its parts 14 expediently with small outlet openings Mistake. Suitable contact material or Reaction material can be stored. The sieve plate is also used for distribution of the gas. An identical sieve plate 17 can of course also be arranged in the tower 2 will. The injected gas makes the liquid layer in all systems in the Tower 1 lighter so that the liquid-air mixture flows quickly upwards while pulls a corresponding amount of liquid out of tower 2 from below, a process which takes place in a constant cycle and an automatic, extremely lively circulation which brings about liquid in the direction of the arrow.

In Fig. B is a series of multi-tower reaction vessels for systematic use Processing of liquids or liquids and solids with gases shown.

In this version, the is filled into the individual systems Liquid interconnected until the end of the reaction. To the systematic The effect of the gas on the liquid is switched through the individual systems appropriate conduction of gas flow each so that the most elaborate Liquid interacts with the freshly entering gas, while the most elaborated gas in the order of loading on the contents the systems with the less elaborated fluid acts. The gas is through the pipe 121, 131, I4I pressed in and from the common gas supply line 18 derived. Every single system is circulating within itself, it is a reaction fluid loaded. In the state of the work process shown in the illustration occurs the gas first enters the system 21. The escaping gas is then through suitable Position of the cock 151 from the system 2I through the pipeline III, I22, I32 in the system 20 and in the same way from the system 20 through faucet I52 and the pipeline II2, I23, I33 passed into the system 19. The gas flows through the system 19 tap I53 and pipe section II3 under a suitable atmospheric pressure through tap I54 into the open air, or it is circulated back into the supply pipeline by a pump 22 18 pressed in.

Instead of the liquid in each case in the individual systems through appropriate You can also work out the switching of the gas outlet systematically work continuously and completely systematically by not just using the gases the order in which it is sent systematically through all systems, but also the Passing liquid continuously through all systems in countercurrent to the gas.

This arrangement is shown in Fig. C.

The pressurized fresh gas enters the system through the pipe 12I, I3I, I34 19 a. The escaping gas collects in 51 and passes through tap 151 and the Pipeline I22, I32, I35 into the system 20. This accumulates in the system 20 Gas in connecting pipe 52 and passes through tap I52 and pipeline I23, I33, I36 in the system 21, in the system the gas collects in the pipe part 53 and enters the open air through the regulating valve tap I53, or it is mediated suitable pipeline 22, 23 and pumping device 24 back into the supply pipeline 121, 131 pressed in. 111, 1 12, 113 are pressure gauges for monitoring the operating pressure.

The liquid emerges from the container 25 through the pipe 26, 27 by means of the pump 28 and pipe 32 in the system 2I, is from here through Pipe 33, pumping device 29, pipeline 34 pressed into the system 2. o. the end the system 20 is supplied with the liquid through pipe 35, pumping device 30 and pipeline 36 pressed over into the system 19. The saturated or elaborated reaction liquid exits system 19 through pipe 37, tap 3I. With this arrangement So if the liquid flows slowly through the individual systems one after the other, namely the direction of flow of the gas flow flowing through the individual systems opposite.

Claims (2)

PATENT CLAIMS: 1. Device for the action of gases on liquids or from gases to a mixture of liquids and solids according to the patent 402509, characterized in that the upper parts of the tower are inserted through a U-shaped tube airtight connects with each other and the diameter of the horizontal connecting pipes approximates the cross-section of the reaction towers. 2. Apparatus with vessels according to claim I, characterized in that that one combines several reaction tower systems to form continuously operating columns.