DE544383C - Process for separating a gas from a gas mixture by means of a finely divided, solid adsorbent which is guided in countercurrent - Google Patents

Description

Method for separating a gas from a gas mixture by an im Countercurrent Finely Parted Solid Adsorbent The present invention relates to a method and apparatus for separating and recovering a Gas from a gas mixture. The term gas is used for both vapors and gases second hand.

The method and direction of this invention can be used to separate two different gases can be applied from each other, provided that they have a sufficient Have boiling point difference. The most common examples of such separations are the separation - of moisture from air or other so-called permanent Gases and the separation and recovery of vapors of highly volatile liquids, such as sulfur dioxide, ither, alcohol, acetone, benzene, gasoline, etc., from mixtures with air or other so-called permanent gases.

The process proceeds in such a way that a gas consists of a gas mixture continuously separated and recovered and the adsorbent material over and over again can be used with the highest possible saturation of the adsorbent with the adsorbent Gas component, in one operation, with a uniform mixture of the adsorbent and the gases and movement of a powdery, solid adsorbent into the gas stream opposite direction.

In the drawings is an apparatus for practicing the invention shown.

Fig. 1 is a schematic elevation of the apparatus according to the invention.

Fig. 2 is an enlarged view of Fig. I.

Fig. 3 is a vertical section through a unit of the adsorber, and Fig. 4 is a section of a. Unit according to line 4-3 in Fig. 2.

The apparatus includes, inter alia. an adsorption apparatus A, whose lower Bottom the gas mixture and its upper bottom the solid adsorbent in such an amount be supplied that this in the form of a rain in an evenly fine distribution gradually over the entire cross-section of the ascending gas flow to be treated moves downwards, collected in the lower part of the adsorber and sent to an activator B is released for regeneration. Then he returns to the upper part of the adsorption apparatus return. The adsorbent describes a circulating current and can be used again will.

The construction of the adsorption apparatus is shown in Figs. 2, 3 and 4 in detail. It consists of a dome 36, an expansion room where in the upper, a separation space II in the lower part and an adsorption chamber I2, which connects the chambers 10 and II. The separation space ii has the one shown in Fig. 2 shape shown and is connected to a line I3 through which the gas or Steam mixture is introduced, as well as to a vent 14 for removing the solid adsorbent. The gas mixture flows into the at the desired speed Working opening I3, which has an average corresponding to a wind player I5, which is connected to the working opening by a channel 16. I7 is a supply pipe of the horn.

The adsorbent is fed into the antechamber through a loading access 37 or introduced the dome after it has been suspended in a non-adsorbable gas was e.g. B. the exhaust gases that have already been used in the adsorber. Of the Expansion space 10 has a larger cross section than the middle part of the adsorber. The lead 37 is relatively small. The latter jumps into the chamber 36 after bent upwards, so that the adsorption material in the necessary change of direction is caused to move down a pipe 35 into the expansion chamber 10. When the exhaust gases carrying the adsorbent enter the chamber 10 through 35, expand they focus on a larger cross-section and their speed decreases. Likewise, the speed of the adsorbent is reduced, which is now evenly Distributed over the entire cross section of the adsorption chamber 12. Now that is true Adsorbent together with the ascending flow of the gas to be treated.

The then onset of adsorption continues while moves the adsorbent through the adsorption chamber 12 downward. Since the adsorption is exothermic runs, the adsorptive capacity of the porous body is sometimes disadvantageous influenced. If a lowering of the temperature proves necessary, the Heat of adsorption can be completely or partially eliminated. This can be done through channels that extend transversely through the adsorption chamber and of a cooling liquid, z. B.

Water, to be flowed through. As the cooling tubes control the flow of the gas mixture and cut through adsorbent, they act like resistances and thus complete nor the mixture of gas and adsorbent. Of course, the construction of the adsorption tower take different forms. In the construction shown in the drawing it consists of several parts, the details of which can be found in Figs. 3 and 4.

Each unit includes a cylindrical part 19 with flanges 20, SO that the neighboring units can be connected to each other. Straight through the unit are laid out a number of parallel tubes 21, which form the shell spaces Connect 22 and 23 on opposite sides of the unit. According to Fig. 3 occurs the cooling water in 24 flows through the jacket space 23, the tube 21 and the Shell 22 and exits the facility at 25. As shown, each unit is four I provided control openings that are closed with cover plates 26. Two each Openings are in each of the two opposite sides of the units.

The adsorption column I2 can consist of as many units as appears necessary for the treatment of the individual gases for which the apparatus is built. The cooling liquid can flow through each unit of the adsorption column individually be, or the outflow opening 25 of the upper unit can according to Fig. 2 with the Feed 24 of the next lower unit are connected.

For further treatment of gas and adsorbent on their way through the Adsorption columns may have tubes 46 placed through one or more units of the column are, which are flowed through by gas from a glass 27, which is through a pipe 17 is connected to the fan 15.

The lower chamber II shows a larger cross-section than the adsorption column, so that the adsorbent can settle on their bottom. This is expediently conical formed and can be emptied into a transport system 28, which is carried out by a screw the adsorbent is conveyed to a purpose-built activator B, which by introduced and at 29 escaping hot gases from a furnace F is heated. That Gas given off by the regenerated adsorbent is withdrawn through 30. The former will from the activator introduced through a screw 3I into a gas stream, from which it taken and fed back to the adsorber.

A fan 32 sucks the exhaust gases from the exhaust opening of the adsorber through a cooler 33 to the filling opening 37. The adsorbent fed into the exhaust gas stream, cooled on the way through the cooler 33 and, in suspended in the exhaust gas stream, fed to the adsorber.

The feed pipe 35 with mouthpiece is displaceable in its longitudinal direction, so that its lower part 35a can be raised and lowered to the introduction to regulate the adsorbent in the ascending gas stream. The to :) opening 35a is built in such a way that the adsorbent sink and not due to the rising gas mixture can escape from a fume cupboard IS. To this end is a part 35b of the supply pipe 35 set up telescopically for up and down movement. this is achieved by a chain 35c, at the end of which a weight 35d the section 35b keeps in balance.

Sometimes it is necessary to strip off some of the adsorbent at 18. For this purpose, the hood 18 can be connected to a cyclone separator 38. In the latter, part of the adsorbent present in the gas is released and reverses through a pipe 39 and a screw 40 back to the cooler 33. That from the separator withdrawing gas passes through a pipe 41 to a fan 32.

Of course, the volume of gas present in the fan 32 is smaller than the volume of exhaust gas leaving the adsorber through I8. The excess of The amount of gas required to fill the fan 32 passes through a channel 42 to an exhaustor 43. The speed of the escaping at 43 and in the fan 32 existing gas must accordingly be regulated by two special fans will.

If necessary, another separator can be used; 1 larger models can be switched on between 42 and 43.

Example I The adsorption system used has a capacity of 28.3 cbm of gas from a Kraelu plant per minute. The gas has one Gasoline content of 4.54 to 6.81 1 per 28.3 cbm of gas, the vapor pressure of the gasoline as determined by the pressure bomb is about 4.54 kg at 380 C.

The gas is saturated with water vapor; accordingly becomes so much Gel introduced into the adsorption system so that all water vapor is removed. 95 <) !, j are absorbed from the gasoline.

90.720 kg of a mesh gel with a grain size of 0.048 to 0.147 mm are introduced into the ad adsorber in the manner indicated in the description. The gel falls down in the adsorber by an ascending gas flow that with a speed of 24.38m per minute in the adsorber rises.

The gas has a medium value when it enters the adsorption tower Temperature of about 280 C, when leaving the cyclone of about 400 C.

Example II From a plant used for the recovery of solvents is determined from an air stream, the following operating data are given: Treated Air volume per minute ................... about 10.9 cbm.

The air stream drawn into the adsorber every minute contains solvents ........... about 230g.

Of this, ethyl alcohol .............. - 54 g, acetone ................. 163 g, ketones ................. 3 g.

The air flow leaving the adsorber every minute still contains Solvents ethyl alcohol ................ about 1.8 g, acetone 5+ g, ................ 6.54g, ketones ................... - o, 54g.

Speed of the air flow in the adsorber chamber about 29.3 m in the min.

Speed of the air flow in the expansion chamber ........ about 5.2m / min.

It has already been proposed in a method of separation of gases from gas mixtures the adsorbent in fine distribution to the one to be separated To supply gas mixture and rectified with this in adsorption storm upwards to move.

The proposal has also already been made to use countercurrent catalysts to trickle down to the rising gas to be treated in the reaction chamber permit.

In contrast, according to the new process, the adsorbent is in one non-adsorbable gas expediently the exhaust gases resulting from the process suspended. The gas is then allowed to expand, creating the adsorbent is excreted from the gas mixture and in the form of a rain in evenly finer Distribution over the entire cross section of the rising gas flow to be treated moving downwards.

By suspending the adsorbent in a non-adsorbable one Gas is primarily achieved when the carrier gas expands to the adsorbent Opportunity is offered to expand to a larger cross-section and a assume a lower flow velocity. As a result of the uniform fine Distribution over the entire cross section of the rising gas flow to be treated and slow downward movement of the adsorbent body with the to be separated Saturate gases approximately to the maximum. Because of the increased saturation, the circulatory Amount of adsorbent is relatively small, so that the size of the entire apparatus can be kept to a minimum. the Construction and manufacturing costs such a system are therefore extremely low.

The adsorbent material suitable for the present invention is from a hard porous powdery gel, e.g. B. silica gel. Other similar ones too Gels such as the oxides of aluminum, tungsten, tin, etc., can be used.

During the adsorption process, the gas mixture becomes the adsorber fed through opening 13 and rises through the adsorber at a rate which allows the absorbent to gradually reverse through the gas flow Direction to sink. The desired contact time between gas and adsorbent can be achieved by Regulation of the speed of the gas flow, through the amount of adsorbent and its degree of fineness can be achieved. One or two preliminary attempts will be the right one Reveal the value of these factors. In practice, speeds of the through the adsorption chamber rising gas flow of 30 to 45 m per minute good results.

Claims (4)

PATENT CLAIMS: 1. Method for separating a gas from a gas mixture by a finely divided, solid adsorbent guided in countercurrent, thereby characterized in that the adsorbent in a non-adsorbable gas, expediently the Exhaust gases produced during the process are suspended, whereupon the gas becomes can expand, whereby the adsorbent is eliminated from the gas mixture and in the form of a rain in an evenly fine distribution over the entire cross-section of the rising gas flow to be treated moves downwards. 2. Apparatus for carrying out the method according to claim I, characterized by arranging an expansion space above the adsorption vessel, in that of the powdered adsorbent introduced in suspension with gaseous agents is finely distributed over the entire cross section of the adsorption container. Apparatus for carrying out the method according to claim 1 characterized by arranging a vertical adsorption tower (A), which has an upper chamber (I0) for receiving the adsorbent suspended in the carrier gas, a dome (36) for supply of the adsorbent and a vent (I8) for the exhaust gases, a separation space (II) and an adsorption chamber connecting the upper chamber and the separation space (I2) comprises, in connection with an activator (B) and one expediently as a cooler acting pipe (33) for returning the adsorbent from the activator to the Adsorption tower. 4. Apparatus for carrying out the method according to claim I, characterized by the arrangement of cooling tubes (2I) in the adsorption chamber.