DE10142946B4 - Apparatus for enriching air with oxygen - Google Patents

Abstract

Apparatus for generating oxygen-enriched breathing air in an aircraft, in which in serial arrangement
a turbine (1) for delivering hot turbine air,
a heat exchanger (2),
two first molecular sieve beds (5, 6) arranged in parallel for the mutual adsorption and desorption of water vapor,
two parallel arranged second molecular sieve beds (10, 11) for the mutual adsorption and desorption of nitrogen and
there is an overflow device (12) generating a purge gas flow between the second molecular sieve beds (10, 11),
and in which a return line (9) running downstream of a second molecular sieve bed (10) to be regenerated via the heat exchanger (2) to the downstream side of a first molecular sieve bed (5) to be regenerated is provided, through which the second molecular sieve bed (10) to be regenerated exiting, from the overflow (12) supplied purge gas is fed to the regenerating first Molekularsiebbett (5) for desorption of the adsorbed water vapor, wherein the purge gas flow downstream of the first Molekularsiebbettes (5) flows into the ambient atmosphere.

Description

The The present invention relates to an adsorptive device Separation of gas mixtures, in particular of air by means of molecular sieve beds.

The Adsorptive separation of gas mixtures by means of pressure swing adsorption is for the most diverse Separation processes have been developed. All separation methods are based on that the gas content of the gas mixture, the higher the affinity to the adsorbent has, in an adsorption step on the surface of Adsorbent is held and the less strongly adsorbed Component are withdrawn from the adsorber filled with the adsorbent can. The desorption of the adsorbed phase is achieved by lowering the pressure after the adsorption step and by rinsing the adsorbent with a part of the enriched gas.

Gas mixtures which consist of different components, must be in individual adsorption stages be treated. For this purpose, various molecular sieve beds arranged one behind the other to selectively remove the components from the gas mixture separate.

An apparatus for selectively separating various components from a gas mixture is known from US 4,447,353 known. An exhaust gas stream is passed through various adsorption beds in the known apparatus to successively remove individual constituents before it is discharged into the atmosphere. After passing through individual adsorption stages and a catalytic combustion furnace, water is removed by cooling the gas in a condenser and the exhaust gas leaving the condenser is then fed to a steam adsorber. For separation of the water vapor from the adsorption and Desorptionstechnik is used, heated for desorption, the saturated adsorption and then the water vapor is rinsed with air. The molecular sieve bed used for the selective removal of water vapor is a type 3A zeolite molecular sieve which also adsorbs a small amount of carbon dioxide. The desorption temperature is about 275 ° C, wherein after reaching the desorption heated air as purge gas is passed through the adsorption bed. After desorption, the adsorption bed is cooled by externally attached water-cooled coils to be ready for the next loading cycle.

adversely in the known device that for the desorption of water vapor a purge gas stream by means of a separately arranged heater on the desorption temperature must be heated. The additional required for this But energy needs are in certain areas of application, for example in airplanes for the production of oxygen-enriched breathing air, not unlimited available.

One known, used in aircraft method for the production of oxygen-enriched breathing air is part of it to divert the heated, compressed air of the engine and after dehumidification of the gas through a molecular sieve bed to adsorb the nitrogen. The adsorption capacity the molecular sieve bed hangs This depends heavily on the efficiency of dehumidification, since moisture the adsorption performance is impaired.

Of the Invention is based on the object, a device for selective Separating a gas component from humid air by means of molecular sieve beds to improve such that at the lowest possible energy consumption a highest possible adsorption capacity achieved in the molecular sieve bed.

The solution The object is achieved with the features of claim 1.

The The object is also achieved with the features of claim 2.

The advantage of the invention consists essentially in the fact that the partial stream of the engine air used for the concentration with oxygen, which exits the engine as superheated, humid air under excess pressure, is first passed through a heat exchanger and thereby cooled, resulting condensate in a water separator collected and the remaining water vapor is then removed completely in a first molecular sieve bed. At the same time, a purge gas stream is heated with the heat exchanger, with which the first molecular sieve bed is regenerated again during the desorption phase. Nitrogen is adsorbed in a second molecular sieve bed connected downstream of the first molecular sieve bed so that the oxygen-enriched air is present at the outlet of the second molecular sieve bed. The desorption of the first Molekularsiebbettes is made so that a partial stream of the oxygen-enriched air is supplied at the exit of the adsorbed in the second Molekularsiebbettes as purge gas to an adjacent second molecular sieve bed to be desorbed. The purge gas is enriched with nitrogen in the second molecular sieve bed to be desorbed, then heated in the heat exchanger and then passed into the first molecular sieve bed to be desorbed. With the thus heated purge gas in the first mole Kularsiebbett located water vapor are particularly well desorbed and sucked by a vacuum source. When operating the device according to the invention in an aircraft, the ambient atmosphere serves as a vacuum source, since the compressed engine air flows with a pressure gradient below the atmospheric absolute pressure which is established at the altitude.

For the second Molecular sieve bed for the separation of nitrogen and oxygen are suitable yourself a 13 X molecular sieve or a 10X molecular sieve with a pore diameter of about 10 angstroms. Can also be used 5 A - molecular sieve, with a pore diameter of 5 Angstroms.

molecular sieves For this Scope are predominantly hygroscopic materials that make traces of water difficult are to be removed. With water separators, which are the molecular sieve could go ahead, only drops and condensate can be collected while the water vapor is allowed through. For example, in one cubic meter of engine air at 30 ° C approximately 30 g of water as water vapor. The water vapor causes in that a zone forms in the molecular sieve in which the molecular sieve contaminated with water and therefore at this point an adsorption of nitrogen is no longer possible is. Due to this moisture influence are molecular sieves for the Adsorption of nitrogen after about 1,000 to 2,000 hours of operation no longer usable and need costly and expensive to be regenerated at the manufacturer.

by virtue of the invention proposed Arrangement with a separate molecular sieve bed for the adsorption of Water vapor can be the adsorption capacity of the downstream second molecular sieve bed clearly increased become. By warming up the purge gas over the heat exchangers on the one hand achieves a high desorption performance of the molecular sieve, has adsorbed the water vapor, and on the other hand by the heat exchangers cooled the air, so that moisture in big Scope as condensate in a water separator before the water vapor adsorbing molecular sieve can be collected. By the proposed according to the invention Arrangement of a heat exchanger between the overpressure source and the molecular sieve bed for the adsorption of water vapor on the one hand cooled down the gas to be treated and on the other hand, a purge gas stream warmed, about the desorption performance for Increase water vapor. Across from the known device comes inventively proposed Arrangement without an additional heating for the purge gas flow.

One embodiment The invention is shown in the figure and explained in more detail below.

The single FIGURE shows a serial arrangement of an overpressure source 1 for the delivery of hot engine air, a heat exchanger 2 , a water separator 3 , a first solenoid valve 4 , two parallel first molecular sieve beds 5 . 6 , a third solenoid valve 7 , a fourth solenoid valve 8th , one the solenoid valves 7 . 8th connecting return line 9 , which are connected to the heat exchanger 2 connected, two parallel second molecular sieve beds 10 . 11 , an overflow device 12 , a fifth solenoid valve 13 and a reservoir 14 for the concentrated oxygen.

The device according to the invention operates as follows: The from the overpressure source 1 escaping hot, with steam-laden air is in the heat exchanger 2 cooled to about 30 ° C and reaches the water 3 where condensate is removed from the air. About the first solenoid valve 4 the air passes through the right first molecular sieve bed 6 directed, where the water vapor is adsorbed. As material for the first molecular sieve beds 5 . 6 a zeolite having a pore diameter of 4 angstroms is suitable.

The dry air is now over the solenoid valves 7 . 8th the right second molecular sieve bed 11 fed, where nitrogen is adsorbed. Oxygen enriched air passes through a pipe 15 in the reservoir 14 ,

The paired first molecular sieve beds 5 . 6 and the second molecular sieve beds 10 . 11 are switched in the interplay of adsorption in the desorption mode. Because the arranged on the right side molecular sieve bed 11 in the illustrated position of the solenoid valves 7 . 8th . 13 in the adsorption mode, the second molecular sieve bed arranged on the left becomes 10 regenerated at the same time. For this purpose, part of the oxygen produced is via the overflow device 12 , in the present case a choke, to the left arranged second molecular sieve bed 10 directed. The left-hand first molecular sieve bed 5 , which is also in regeneration mode, is via the first solenoid valve 4 with a vacuum source 16 connected. As a result, a purge gas flow through the two molecular sieve beds 5 . 10 and, in the first instance, the second molecular sieve bed arranged in the left-hand side 10 bound nitrogen desorbed. The purge gas flow is then via the return line 9 to the heat exchanger 2 and from there via the second solenoid valve 7 to the left arranged first molecular sieve bed 5 where the now warmed up nitrogen desorbs the water vapor.

By heating the purge gas stream in the heat exchanger 2 Its capacity to absorb water is greatly increased because the hot nitrogen can be enriched to the saturation limit with moisture.

At the next cycle, not shown in the figure, the molecular sieve beds adsorb 5 . 10 while the molecular sieve beds 6 . 11 regenerate.

If used as an overpressure source 1 a turbine is used in an aircraft and the oxygen enriched air is the hot turbine air exiting the turbine under pressure is not a separate source of vacuum 16 required, provided that the purge gas flows into the atmosphere below the absolute ambient pressure which occurs at the altitude.

Claims (2)

Device for generating oxygen-enriched breathing air in an aircraft, in which a turbine (in serial arrangement) 1 ) for the delivery of hot turbine air, a heat exchanger ( 2 ), two parallel arranged first molecular sieve beds ( 5 . 6 ) for the mutual adsorption and desorption of water vapor, two second molecular sieve beds ( 10 . 11 ) for the mutual adsorption and desorption of nitrogen and a purge gas flow between the second molecular sieve beds ( 10 . 11 ) generating overflow device ( 12 ), and in which a downstream molecular sieve bed to be regenerated ( 10 ) over the heat exchanger ( 2 ) to the downstream side of a first molecular sieve bed to be regenerated ( 5 ) extending return line ( 9 ), through which the second molecular sieve bed to be regenerated ( 10 ) exiting, from the overflow device ( 12 ) supplied purge gas stream to be regenerated first molecular sieve bed ( 5 ) is fed to the desorption of the adsorbed water vapor, wherein the purge gas stream downstream of the first Molekularsiebbettes ( 5 ) flows into the ambient atmosphere. Use of a heat exchanger ( 2 ) in a device for the enrichment of air with oxygen between a turbine ( 1 ) for the delivery of hot turbine air and an arrangement with two parallel arranged first molecular sieve beds ( 5 . 6 ) for the mutual adsorption and desorption of water vapor for heating one of the first molecular sieve beds ( 5 . 6 ) regenerating purge gas stream, wherein the purge gas stream downstream of the first molecular sieve beds ( 5 . 6 ) flows into the ambient atmosphere.