DE102008005439B3 - Method for separating carbon dioxide from gas mixtures by centrifuge, involves continuously filling gas mixture from external connection into rotary drum - Google Patents

Abstract

The method involves continuously filling gas mixture (1) from an external connection (3) into a rotary drum (4) and attaching for the rotation. A separation of the carbon dioxide is carried out with certain density that is higher than the densities of all other components of the gas mixture. The separated carbon dioxide fills into a ring shape chamber (16) from bottom to top. An independent claim is included for a centrifuge for the execution of carbon dioxide separation method.

Description

The The invention relates to a method and a centrifuge for Separation of carbon dioxide from gas mixtures. It is It is a machine for the radial acceleration of gases Purpose of the separation, generally called centrifuge. machinery of this type are known in principle and are used for the separation of gaseous Uranium combinations of different uranium isotopes by the density differ from each other, used. These machines have but a strange construction with extremely many separation levels (Centrifuge series), because they have to Gases with extremely low Separate density differences.

centrifuges for separating a heavy gas component from a gas mixture have been known for a long time.

That's how it shows DE 88 07 684 U1 a centrifuge for separating oxygen from nitrogen from an air mixture, the centrifuge having a drum rotating about a vertical axis, which is divided into sectors by radial ribs. The mixture to be separated is supplied via a central supply line into the drum, from which the separated portions flow through openings at the bottom of the outer wall of the drum in such a way that substantially the heavier gas component in an outer annular chamber and the lighter gas components themselves accumulate in an internal annular chamber. The separated gas components can then be withdrawn via downwardly disposed outlet openings from the respective co-rotating annular chambers.

The US 4 292 051 A also describes a very similar centrifuge with a horizontal drum axis for a comparable purpose. The supply takes place from one side into a on both sides slidably, with radial ribs into segments divided drum and the discharge on the opposite side of the drum via outer openings for the heavy component and internal openings for the lighter gas components in the respective fixed annular chambers; Pumps can also be provided to assist the flow.

None However, the known devices discloses a device with a ring chamber designed as a fixed collecting chamber, the periodically filled is where the heavy component displaces the lighter components and this in countercurrent through the drum through a central discharge outward be dissipated.

The The present invention has as its object the separation of carbon dioxide as a gas with a significantly higher density than the other components to allow the injected gas mixture. To the grading separation To avoid, which requires very many rotary cylinders, has the present invention uses another principle, which is a slow Accumulation of carbon dioxide used in a standing chamber the separation being per se by the centrifugal force.

The solution This problem is solved by a procedure with the characteristics of Claim 1 and by a centrifuge with the features of the claim Second

So the proposed device according to the invention is relatively simple, reliable and lets himself go for larger or use very small amounts of carbon dioxide and gas mixtures as well as throughputs.

Further advantageous embodiments of the invention are characterized in the subclaims.

One embodiment the device according to the invention is shown in the drawings and will be explained in more detail below.

It shows:

1 Longitudinal section through the centrifuge

2 Cross section through the centrifuge (section AA)

by virtue of The figures become closer to the function explained.

The figures show a centrifuge in which the gas mixture 1 within a fixed axial feed 2 , from the outside connection 3 Coming, in the drum 4 , supported by the lower plain bearing part 5 with the lower part of the drum 4 in the lower fixed bearing part 6 the axial feed 2 and further supported by the upper sliding bearing part 7 with the upper part of the drum 4 in the upper fixed bearing part 8th with the upper fixed discharge 9 , is conducted so that over time, under the action of centrifugal force on the gas mixture 1 that, being rotated by the radial ribs 10 extending from the central shaft 11 to the periphery of the drum 4 Separating the carbon dioxide gas with a higher specific gravity than the densities of all other components of the gas mixture 1 in the direction of the outer wall 12 the drum 4 by flowing along the lower wall "a" of the drum 4 takes place, by a row of breakthroughs 13 in the lower wall a of the drum 4 , this heavier gas component 14 by the action of gravitation together with increased partial pressure flows down and the lighter gas mixture 15 located in the fixed annular chamber placed underneath 16 replaced the centrifuge and thus pushed upwards, where it along the upper wall b of the drum 4 in the direction of its central shaft 11 is printed and then through the upper fixed discharge 9 through the discharge nozzle 17 reaches the outside, with the carbon dioxide gradually the fixed annular chamber 16 filling from bottom to top, with the top carbon dioxide sensor 18 the reaching of the upper level signals and at the same time the switching on of the high-pressure pump 19 causes, so that the carbon dioxide through the neck 20 that almost reaches the bottom of the fixed ring chamber 16 extends through the exhaustion 21 , axial bore 22 and connecting pieces 23 the collection chamber 24 into the connected high-pressure bottle 25 is filled during the pumping operation, the level of carbon dioxide in the fixed annular chamber 16 decreases, until later the level of the lower carbon dioxide sensor 44 is achieved, this being the signal for switching off the high-pressure pump 19 while pumping through the series of breakthroughs 13 the native gas mixture from the external connection 3 passes and the pumped carbon dioxide replaced, after stopping the high-pressure pump 19 the described cycle of carbon dioxide collection in the stationary annulus 16 takes place again, these cycles being repeated until the high pressure bottle 25 is full and is replaced by a new one.

The upper part 26 the fixed annular chamber 16 also has some fixed radial ribs 27 extending from the outer wall to the annular recess around the feeder 2 Making a revolving neck 20 allowed to extend, allowing it to rotate the gas in the fixed annular chamber 16 prevent.

At least part of the upper part 26 the fixed annular chamber 16 is removable, allowing a maintenance removal of the accumulated dust particles in the annular storage space 28 of the upper part 26 the fixed annular chamber 16 allowing all the fixed parts through fits and screws 45 held together.

The drum 4 is from the radial ribs 10 divided into sectors with different radius, each sector has a constant maximum radius R _{m of} the outer wall 12 in the middle as well as radial breakthroughs 29 which normally has a flexible band 30 closed to the outside, this flexible band 30 from an electromagnet 31 laterally on the outer wall 12 can be moved so that the outer breakthroughs 32 in the flexible band 30 over the radial openings 29 come and so the discharge of the dust particles under pressure in the course of operation by the centrifugal force to the outer wall 12 in the adjoining room of the upper cover 33 associated with the upper fixed feeder 9 allow the electromagnet with electric current through the contact rings 34 by means of carbon sander 35 connected to an external controller 36 guided by lines through the axial channel 37 is supplied and by the spring 38 close to the outside wall 12 is held.

The electric motor 39 whose stator 40 attached to the lower part of the fixed axial feed 2 is and its rotor 41 at the central shaft 11 fixed, power the centrifuge.

The electric motor 39 has the windings of the stator 40 and rotors 41 connected in series, with the direct current through the collector 42 with carbon grinder 43 is fed.

Claims (8)

Process for the separation of carbon dioxide from gas mixtures by means of a centrifuge, wherein the gas mixture ( 1 ) from an external connection ( 3 ) in a rotating drum ( 4 ) is continuously filled and made to rotate and a separation of the carbon dioxide with a higher density than the densities of all other components of the gas mixture ( 1 ) when flowing along the lower wall (a) of the drum ( 4 ) in the direction of the outer wall ( 12 ) of the drum ( 4 ) takes place, the separated carbon dioxide ( 14 ) through a series of breakthroughs ( 13 ) in the lower wall (a) of the drum ( 4 ) and near the periphery of the drum ( 4 ) under the action of gravity down into one under the drum ( 4 ) arranged stationary annular chamber ( 16 ) flows while the lighter gas components ( 15 ) from the annular chamber ( 16 ) of carbon dioxide ( 14 ) and through the breakthroughs ( 13 ) and along the upper wall (b) of the drum ( 4 ) in the direction of a central shaft ( 11 ), from where they are conducted to the outside as residual gas and wherein the separated carbon dioxide ( 14 ) gradually the fixed annular chamber ( 16 ) from bottom to top, wherein the degree of filling of the annular chamber ( 16 ) by means of an upper and a lower carbon dioxide sensor ( 18 . 44 ) is monitored to, when the annular chamber ( 16 ) is filled with carbon dioxide, with the aid of a high-pressure pump ( 19 ) and, when the carbon dioxide from the annular chamber ( 16 ), the high pressure pump ( 19 ) switch off, wherein during the pumping operation through the openings ( 13 ) Gas mixture ( 1 ) from the external connection ( 3 ) is replaced and the pumped carbon dioxide replaced and wherein after stopping the high-pressure pump ( 1 ) the described cycle of the collection of carbon dioxide in the annular chamber ( 16 ) is repeated and these cycles are repeated until a certain amount of carbon dioxide is reached. Centrifuge for carrying out the method according to claim 1, wherein an external connection ( 3 ) and a fixed axial feed ( 2 ) about the rotating vertical central shaft ( 11 ) the feed for the gas mixture ( 1 ) to a drum ( 4 ) connected to the central shaft ( 11 ), which at the bottom by a lower plain bearing part ( 5 ) associated with the lower wall (a) of the drum ( 4 ) in the lower fixed bearing part ( 6 ) of the axial feed ( 2 ) and further top by an upper plain bearing part ( 7 ) belonging to the upper wall (b) of the drum ( 4 ) in an upper bearing part ( 8th ) belonging to a fixed upper discharge ( 9 ), wherein radial ribs ( 10 ) connected to the central shaft ( 11 ), the lower wall (a), the upper wall (b) and the periphery of the drum ( 4 ), the supplied gas mixture ( 1 ) during operation, whereby under the drum ( 4 ) a fixed annular chamber ( 16 ), whereby breakthroughs ( 13 ) in the lower wall (a) of the drum ( 4 ) the way for the circulation of gas components between drum ( 4 ) and annular chamber ( 16 ), the level of the separated carbon dioxide ( 14 ), which the annular chamber ( 16 ) from bottom to top, from an upper carbon dioxide sensor ( 18 ) and a lower carbon dioxide sensor ( 44 ) is monitored, their signals for controlling a high pressure pump ( 19 ), which serve as a drain pump for the separated carbon dioxide ( 14 ) and this from below from the annular chamber ( 16 ) into a connected exchangeable high-pressure bottle ( 25 ) subtracts. Apparatus according to claim 2, characterized in that the from the annular chamber ( 16 ) removed carbon dioxide through a nozzle ( 20 ), a feeder ( 21 ), an axial bore ( 22 ) in the central shaft ( 11 ) and a connecting piece ( 23 ) via a collection chamber ( 24 ) to the high pressure pump ( 19 ) and the associated high-pressure bottle ( 25 ). Device according to claim 2 or 3, characterized in that the upper part ( 26 ) of the fixed annular chamber ( 16 ) fixed radial ribs ( 27 ) extending from the outer wall of the annular chamber ( 16 ) to the annular recess around the feed ( 2 ), so that a rotation of the nozzle ( 20 ) is possible, but a rotation of the gas in the fixed annular chamber ( 16 ) is impeded. Device according to one or more of claims 2 to 4, characterized in that at least a part of the upper part ( 26 ) of the fixed annular chamber ( 16 ) is removable and a maintenance removal of the accumulated dust particles in the annular storage space ( 28 ) of the upper part ( 26 ) of the fixed annular chamber ( 16 ), whereby all fixed parts are replaced by fits and screws ( 45 ) are held together. Device according to one or more of claims 2 to 5, characterized in that the drum ( 4 ) of the radial ribs ( 10 ) are divided into sectors with different radii, each sector having a central region with a constant maximum radius R _{m of} the outer wall ( 12 ) as well as radial breakthroughs ( 29 ), which in normal operation by a flexible band ( 30 ) are closed to the outside, which also with breakthroughs ( 32 ) provided band ( 30 ) of an electromagnet ( 31 ) laterally on the outer wall ( 12 ) can be moved so that the outer openings ( 32 ) of the band ( 30 ) over the radial openings ( 29 ) and thus the discharge of the dust particles under pressure during operation by the centrifugal force from the outer wall ( 12 ) in the adjoining space of the upper cover ( 33 ) associated with the upper feeder ( 9 ), the electromagnet ( 31 ) in an axial channel ( 37 ) guided lines ( 34 ) and coal grinders ( 35 ) connected to an external controller ( 36 ), is supplied with electricity and the tape ( 30 ) by a spring ( 38 ) close to the outer wall ( 12 ) is held. Device according to one or more of claims 2 to 6, characterized in that an electric motor ( 39 ) whose stator ( 40 ) at the lower part of the fixed axial feed ( 2 ) and its rotor ( 41 ) at the central shaft ( 11 ), which drives centrifuge. Device according to one or more of claims 2 to 7, characterized in that the electric motor ( 39 ) the windings of the stator ( 40 ) and rotor ( 41 ) has been connected in series, the direct current through the collector ( 42 ) with carbon grinders ( 43 ) is fed.