WO2023088781A1 - Utilization of carbon dioxide from ambient air - Google Patents

Abstract

The invention relates to the utilization of carbon dioxide contained in the ambient air. A system and a method are disclosed, by which the carbon dioxide can be separated and utilized.

Description

Utilization of carbon dioxide from the ambient air

DESCRIPTION:

The invention relates to the utilization of carbon dioxide contained in the ambient air. A system and a process are presented with which the carbon dioxide can be separated and used.

Direct Air Capture (DAC) is a process for extracting carbon dioxide (CO2) directly from the ambient air. The basic principle is that ambient air flows through a filter that removes part of the CO2. The result of the process is pure CO2, which can then be used for various purposes.

Possible uses of CO2 are the material use as a raw material, e.g. for the chemical industry, the production of CCh-neutral fuels (EE gas and e-fuels) and the geological storage of carbon dioxide, which can result in negative emissions. The latter is known as Direct Air Carbon Capture and Storage (DACCS) and is intended to actively remove carbon dioxide from the atmosphere and store it permanently via CO2 capture and storage (Carbon Capture and Storage, CCS) in order to counteract global warming .

Large fans are required to extract CO2, which push the ambient air through a filter. There is an adsorber material in the filter. Various liquid or solid adsorber materials from different chemical substance classes are used. In the amine wash, a liquid solvent made from organic amines is used, in other processes sodium hydroxide, for example, is used as a CC absorber CO2 reacts to form sodium carbonate. Alternatively, the CO2 binds to a solid sorbent.

The technique mostly comprises two steps, an adsorption step and a desorption step. In the adsorption step, air is passed over the adsorber, the CO2 from the air is bound to the adsorber, the remaining air components leave the adsorber cartridge. When the adsorber is saturated with CO2, the desorption step is performed. The CO2 is expelled from the cartridge either by heat input or by inert gas; a slight vacuum can also be advantageous. Pure CO2 is obtained, which can now be used for various purposes or for final storage.

US 5,779,767 relates to a process for the adsorption of at least carbon dioxide, water and nitrogen oxides and acetylene from a gas stream, in which the gas is contacted with an adsorbent mixture of a zeolite and an alumina. The process may be operated as a swing adsorption process in which the gas is contacted with the adsorbent at a first temperature and pressure to adsorb at least carbon dioxide, water and nitrogen oxides therefrom and the adsorbent by reducing the pressure and/or increasing the temperature is periodically regenerated.

EP 0 862 938 A discloses a pressure swing adsorption process for removing nitrogen oxides, carbon dioxide and water from gases. The gas stream is passed through an alumina adsorbent and a zeolite adsorbent, preferably 13X zeolite, at elevated pressure. The pressure swing adsorption process comprises the steps of: (a) adsorption of water, carbon dioxide and nitrogen oxides at elevated pressure; (b) countercurrent depressurization; (c) countercurrent purging with nitrous oxide-depleted gas; and (d) repressurizing with nitrous oxide depleted gas. EP 1 101 521 A1 provides a multi-component adsorbent mixture that removes water, carbon dioxide and nitrogen oxides and/or hydrocarbons from air. The mixture includes a third adsorbent that selectively adsorbs selected nitrogen oxides, hydrocarbons, or both. The water vapor selective adsorbent is activated alumina. The carbon dioxide selective adsorbent is zeolite 13X. The third adsorbent is zeolite 5A, which selectively adsorbs nitrous oxide, ethylene and propane.

EP 0 766 989 A1 discloses a method for removing at least two contaminating gas components from a feed gas stream, comprising performing repeated operating cycles. The feed gas stream is contacted in a feed direction at a first pressure and at a first temperature with a solid adsorbent capable of adsorbing a first of the impurity gas components more strongly and a second of the impurity gas components less strongly such that the first impurity gas component is adsorbed in an upstream portion of the adsorbent and the second impurity gas component is mainly adsorbed in a downstream portion of the adsorbent. The feeding of the feed gas stream is stopped and the gas in contact with the adsorbent is depressurized to a second, lower pressure at which a regeneration gas at a second temperature, higher than the first temperature, is emitted in a direction opposite to the feeding direction of the feed gas stream in Contact with the adsorbent is fed to generate a heat pulse moving in the countercurrent direction to desorb the less strongly adsorbed second impurity gas component from the downstream (with respect to the feeding direction) section by thermal swing adsorption, while at the same time the more strongly adsorbed first impurity gas component is desorbed from the upstream (with respect to the feeding direction) section by pressure swing adsorption. The supply of regeneration gas is terminated before the heat pulse travels to the upstream section and the adsorbent is repressurized. US 4,249,915 A discloses a process in which moisture and CO2 are removed from atmospheric air by adsorption in separate beds. The moisture-laden bed is regenerated by pressure swing adsorption in a relatively short duty cycle, while the CO2-laden bed is thermally regenerated at significantly longer time intervals. The process is used in connection with the pretreatment of air prior to cryogenic distillation to separate oxygen and nitrogen therein.

WO 2021/206 564 A1 describes a method and an arrangement for removing CO2 from ambient air or flue gases, wherein a pre-cooled flow of the air or gases is passed through a bed of CO2 adsorption material in a first direction, whereby CO2 is removed the flowing air or gas is adsorbed in the CO2 adsorbent bed. A flow of warm fuel gas from a thermal storage unit is directed to the CO2 adsorbent bed in a second direction opposite to the first direction to transfer stored heat from the heat recovery unit to the CO2 adsorbent bed while simultaneously transferring cold from the adsorbent bed to the thermal storage. The heating gas is then passed through the CO2 adsorbent bed in a closed loop, with CO2 being desorbed from the CO2 adsorbent bed. The desorbed CO2 is extracted for use or storage, then a cooling gas flow is passed through the thermal storage unit and the CO2 adsorbent bed in the first direction, with low-temperature heat being transferred to the CO2 adsorbent bed and high-temperature heat being transferred from the CO2 adsorbent bed to the thermal storage unit.

There are now a number of materials that are capable of CO2 uptake within a DAC system, however, the materials either absorb relatively high CO2 concentrations, in which case desorption is energy-intensive, or the selective binding of CO2 to the adsorber is not very high, then the overall efficiency is low and the cost of CO2 abatement is high.

Against this background, the invention has set itself the task of providing a method and a system for reducing the concentration of carbon dioxide in the ambient air and for using the carbon dioxide removed from the ambient air, which are efficient, robust and inexpensive.

The object is achieved according to the invention by a method having the features of claim 1 and a system having the features of claim 6. Refinements and developments of the invention result from the dependent claims.

The subject matter of the invention is a method for the utilization of carbon dioxide contained in the ambient air. The method according to the invention comprises the drying of an ambient air flow in a dehumidification unit, then the adsorption of carbon dioxide from the dried air flow in an adsorber unit, which contains an adsorber material for CO2, and then the desorption of adsorbed carbon dioxide from the adsorber unit, the adsorption of carbon dioxide being so is carried out for a long time until a termination criterion is reached, and then the desorption of carbon dioxide takes place.

The drying of the ambient air flow takes place in a two-stage process, which involves pre-drying of the air flow in a continuously operating electrically operated pre-dryer, which is a continuously operating adsorption dryer, and subsequent passage of the pre-dried air flow through a silica gel, molecular sieve 3A, sodium sulphate, magnesium sulphate, activated alumina or zeolite A comprising desiccant-filled drying device comprises.

The adsorption of carbon dioxide from the dried air flow takes place at atmospheric pressure and a temperature in the range from 20°C to 35°C, and for Desorption of adsorbed carbon dioxide from the adsorber unit, the adsorber material in the adsorber unit is heated to a temperature in the range from 100° C. to 300° C. and a negative pressure in the range from 10 to 50 mbar is generated in the adsorber unit.

Carbon dioxide (CO2) is adsorbed from the ambient air in a stationary adsorber unit. For this purpose, a stream of ambient air is passed through a stationary adsorber unit. In the adsorber unit, the air flow is first dried, i.e. the water contained in the air flow is removed. The drying takes place in a two-stage process. First, the air flow is pre-dried by an electrically operated pre-dryer, which is a continuously operating adsorption dryer. The pre-dryer works independently of the pressure and removes approx. 30 to 50% of the moisture contained in the air. In one embodiment, the pre-drying takes place at an air flow temperature of at most 20°C.

In a second stage, the pre-dried air is passed through a drying device filled with a drying agent in order to remove residual moisture. The desiccant is selected from silica gel, molecular sieve 3A, sodium sulfate, magnesium sulfate, activated alumina and zeolite A. In one embodiment of the method, the residual moisture content of the air flow after drying is less than 1 g/m ³ .

Carbon dioxide contained in the dried air flow is then adsorbed. The adsorber unit is thus charged with CO2. In one embodiment of the method, this step is carried out until a termination criterion is reached, for example until the carbon dioxide uptake capacity limit of the adsorber unit is reached. In a further embodiment of the method, this step is carried out until a predetermined period of time has elapsed. The air flowing out of the adsorber unit is depleted in carbon dioxide.

The adsorber unit contains an adsorber material that can bind carbon dioxide, and the carbon dioxide is th adsorber material adsorbed. In one embodiment, the adsorber material comprises at least one inorganic material from the class of aluminosilicates. In one embodiment, the adsorber material is a zeolite. In a further embodiment, the adsorbent material comprises zeolite 13X or molecular sieve 13X or a modification thereof.

In one embodiment, the adsorbent material is used in granular form. In a further embodiment, the adsorbent material consists of particles with a grain size, i.e. an equivalent diameter, in the range from 1 to 5 mm. In one embodiment, the adsorber material is present as a bed in a filter module of the adsorber unit. In a further embodiment, a container that is permeable to the air flow is filled with the adsorber material in a filter module of the adsorber unit.

The carbon dioxide is adsorbed at a temperature in the range from 20° C. to 35° C. at atmospheric pressure. The drying of the air flow is particularly efficient at temperatures below 20°C. The adsorption of carbon dioxide is also favored by low temperatures, since the process is exothermic.

The first step of the method according to the invention is carried out at normal pressure, so there is no compression of the ambient air flow introduced.

After completion of the first step of the method according to the invention, for example after reaching the capacity limit of the adsorber unit or after the end of a predetermined period of time, the air flow through the adsorber unit loaded with carbon dioxide is interrupted and the adsorbed carbon dioxide bound in the adsorber unit is then desorbed. In one embodiment, the predetermined period of time is from 2 hours to 5 hours, for example 4 hours. In one embodiment, the carbon dioxide is desorbed from the adsorber unit by heating the adsorber material in the adsorber unit and reducing the pressure. As a result, the adsorbed CO2 is converted into the gas phase and the filter module is regenerated. The CO2 separated from the adsorber unit is put to further use. In one embodiment, the duration of the desorption phase is from 1 hour to 3 hours, for example 2 hours.

For desorption, the loaded adsorption material is heated to a temperature in the range from 100° C. to 300° C., for example 200° C. to 300° C., or 250° C. to 300° C., and a negative pressure in the range from 10 to 50 mbar (1,000 to 950 mbar absolute).

In a further embodiment of the method, the loaded adsorption material is heated to a temperature in the range from 100° C. to 150° C. for desorption and an auxiliary gas is passed through the adsorber unit. In one embodiment of the method, the auxiliary gas is ambient air. In a further embodiment of the method, the adsorber unit is filled with the auxiliary gas, then a negative pressure in the range of 10 to 50 mbar (1000 to 950 mbar absolute) is generated in the adsorber unit in order to suck off the released CO2 and the auxiliary gas. In one embodiment of the method, the filling and suction is repeated several times, for example two or three times.

After the desorption has ended, the adsorber unit is allowed to cool down to room temperature or the adsorber material is actively cooled. In one embodiment, a new phase of adsorption is started directly after the end of desorption, ie ambient air is passed through the adsorber unit again while it is cooling down. As soon as the adsorber material has cooled down sufficiently, it binds CO2 from the ambient air flow again. In one embodiment, it takes about 1 hour for the first CO2 molecules to stick again. In one embodiment of the method, to regenerate the drying agent in the drying device, the loaded drying agent is heated to a temperature in the range from 100° C. to 150° C., for example 100° C. to 120° C., and a negative pressure is created in the drying device in the range from 10 to 50 mbar (1000 to 950 mbar absolute). In one embodiment, the regeneration lasts from 45 minutes to 90 minutes, for example 1 hour.

In one embodiment of the process, this is carried out continuously, i.e. the adsorption step and desorption step take place alternately in succession.

The method according to the invention offers a number of advantages, in particular it can contribute to reducing environmental pollution and energy consumption. The carbon dioxide is thus removed from the atmosphere or the ambient air of the adsorber unit. By using the method according to the invention, significant amounts of carbon dioxide can be removed from the ambient air in polluted zones, e.g. on busy roads or in tunnels. The carbon dioxide content of the air can be significantly reduced in tunnels.

The carbon dioxide contained in the ambient air, e.g. from the exhaust gases of internal combustion engines, is made industrially usable by the method according to the invention, since it is available in concentrated form after desorption and is no longer diluted by the other air components.

The invention also relates to a system for utilizing carbon dioxide from the ambient air. The system has an inflow opening which is fluidically connected to an outlet opening which has a blower or a fan so that an air duct is formed and air is sucked in from the environment and guided through a dehumidification unit and an adsorber unit. The dehumidification unit is designed to dry an ambient air flow supplied to the system, and the adsorber unit is set up to bind carbon dioxide from the dried ambient air flow during an adsorption phase and release bound carbon dioxide during a desorption phase. The system includes a desorption module which is set up to desorb carbon dioxide adsorbed in the adsorber unit from the latter. The system comprises heating means to introduce heat into the adsorber unit during the desorption phase and negative pressure means to create a negative pressure in the adsorber unit during the desorption phase. The dehumidification unit comprises a continuously operating, electrically operated pre-dryer, which is a continuously operating adsorption dryer, and a drying device downstream of this, which is filled with a desiccant comprising silica gel, molecular sieve 3A, sodium sulphate, magnesium sulphate, activated alumina or zeolite A.

The system has a stationary adsorber unit, which is set up to adsorb carbon dioxide from the ambient air, and a desorption module, which is set up to desorb carbon dioxide adsorbed in the adsorber unit from the latter. The system is particularly suitable for carrying out the method according to the invention.

The system includes an adsorber unit that is set up to adsorb carbon dioxide (CO2) from the ambient air. In one embodiment, the adsorber unit comprises a housing with at least one inflow and outflow opening in the housing wall, a filter module inside the housing, which is fluidically connected to the inflow and outflow opening, so that an air duct is formed, and an air intake device, to suck in air from the environment and lead it through the filter module. In one embodiment, the air induction device is a fan. In another embodiment, the air intake device is a fan. In one embodiment, the air intake device is designed for a nominal air flow of 1,000 to 15,000 m ³ /h, for example 8,000 to 12,000 m ³ /h. A blower power or fan power in the range of 1 to 15 kW is required for this. A drying device or dehumidifying device is provided in the air duct of the adsorber unit, which removes water from the air flow before it enters the filter module. The drying of the air stream prevents the adsorption capacity of the adsorber material for carbon dioxide from being reduced by water loading.

The drying device comprises a continuously operating, electrically operated pre-dryer, which is a continuously operating adsorption dryer. In one embodiment, the pre-dryer has a power consumption in the range from 9 kW to 15 kW.

The drying device comprises, downstream of the pre-dryer, a unit with a desiccant that removes water from the air flow. The desiccant is selected from silica gel, molecular sieve 3A, sodium sulphate, magnesium sulphate, activated alumina and zeolite A.

The adsorber unit contains an adsorber material which is set up to bind carbon dioxide (CO2) by adsorption. In one embodiment, the adsorber unit contains a CO2-binding agent based on aluminum silicate, which has an adsorption capacity for pre-dried CO2 of up to 20% by weight. In a special embodiment, the adsorber material includes aluminosilicates, for example amorphous aluminum silicate. In one embodiment, the adsorber material is a zeolite. In a further embodiment, the adsorbent material comprises zeolite 13X or molecular sieve 13X or a modification thereof.

In one embodiment, the adsorbent material is used in granular form. In a further embodiment, the adsorber material consists of particles with a grain size, ie an equivalent diameter, in the range from 1 to 5 mm. In one embodiment, the adsorber material is present as a bed in a filter module of the adsorber unit. In a further embodiment, a container that is permeable to the air flow is filled with the adsorber material in a filter module of the adsorber unit. In one embodiment, a CO2 sensor is arranged at the outlet of the adsorber unit, which measures the CC content of the exiting gas stream. During the adsorption phase, the CC content of the exiting gas stream is very low. After the capacity limit of the adsorber material has been reached, the CC content of the exiting gas stream increases rapidly ("breakthrough"). The CO2 sensor therefore makes it possible to quickly and reliably detect when the capacity limit of the adsorber material has been reached.

In one embodiment, the adsorber unit is a stationary system that is used in locations where high concentrations of carbon dioxide in the air occur, e.g. in urban areas, on busy roads or in tunnels. In one embodiment, the adsorber unit is mounted in a tunnel, e.g., on the tunnel ceiling. There can also be several adsorber units in one tunnel. In another embodiment, the stationary adsorber unit is arranged outside the tunnel and an air flow is sucked out of the inside of the tunnel via suitable devices, passed through the adsorber unit and then fed back into the tunnel.

In an exemplary embodiment, the adsorber unit is designed for a nominal air flow of 1,000 to 15,000 m ³ /h, for example 8,000 to 12,000 m ³ /h. This requires a fan power in the range from 1 to 15 kW, in particular from 1 to 5 kW, for example from 2 to 3 kW.

The system according to the invention comprises a desorption module which is set up to desorb carbon dioxide adsorbed in the adsorber material from the latter. In the desorption module, the CO2 is released from the adsorber material saturated with CO2 through the combination of heat and slight negative pressure. Any impurities remain on the adsorber material. The pure CO2 is extracted and leaves the desorption module almost without pressure. It can then be used directly.

In one embodiment, the desorption module is set up to reduce the pressure in a filter module filled with an adsorber material and to heat the adsorber material and thereby desorb carbon dioxide from the filter module and suck it out of the filter module.

In another embodiment, the desorption module is set up to introduce an auxiliary gas into a filter module filled with an adsorber material and to heat the adsorber material and thereby desorb carbon dioxide from the filter module and discharge it from the filter module.

It goes without saying that the features mentioned above and those still to be explained below can be used not only in the combination specified in each case, but also in other combinations or on their own, without departing from the scope of the present invention.

The invention is illustrated below using an exemplary embodiment and is further described with reference to the example and the associated drawing. It shows.

FIG. 1 shows a schematic representation of an embodiment of the system according to the invention for the utilization of carbon dioxide.

FIG. 1 schematically shows an embodiment of the system 10 according to the invention for the utilization of carbon dioxide. An air flow containing carbon dioxide is fed into the air inlet 11 of a dehumidification unit 12, which is set up to remove water from the air flow and contains, for example, a desiccant. In one embodiment, the dehumidification unit is preceded by an electrically operated pre-dryer. The dried air stream is fed into an adsorber unit 13 which is set up to adsorb carbon dioxide (CO2) from the dried air stream and contains an adsorber material for carbon dioxide. The one on Koh The air flow depleted in carbon dioxide leaves the adsorber unit 13 through an air outlet 14 equipped with a fan or blower. During operation, adsorption of CO2 takes place in the adsorber unit 13. The adsorber unit 13 is thereby charged with CO2 and can absorb CO2 up to the absorption limit of the adsorber unit.

A desorption module 15 is set up to generate a negative pressure in the adsorber unit 13 and to heat the adsorber material contained in the adsorber unit 13 . As a result, the adsorbed carbon dioxide is desorbed and sucked off. The CO2 goes into the gas phase, the adsorber material is regenerated. In the illustrated embodiment, the desorption module 15 is also set up to create a negative pressure in the dehumidification unit 12 and to heat the desiccant contained in the dehumidification unit 12 in order to regenerate the desiccant.

Experimental investigations were carried out with a prototype demonstration plant. In the dehumidification unit 12 was 1 ton of silica gel with a surface area of> 300 m ² / g and a bulk density of 690-785 kg / m ³ filled and in the adsorber unit 13 was 1 ton of zeolite particles with a nominal pore diameter of 0.8 nm, a mean particle diameter of 2 mm and a bulk density of 660 kg/m ³ . After the plant was started up, an immediate, rapid drop in the CO2 concentration from 440 ppm to 163 ppm and then further to 29 ppm was measured at outlet 14. Controlling the dew point/humidity in the dehumidification unit 12, which was 0.5 g/m ³ in the experiment, is decisive for efficient CO 2 absorption in the adsorber unit 13 .

The adsorption of moisture in the dehumidification unit 12 and of CO2 in the adsorber unit 13 caused a temperature increase from approx. 28° C. to 33° C., since both adsorption processes are exothermic.

Even under unfavorable conditions (25° C., 12 g/m ³ humidity) air with a carbon dioxide content of 440 ppm was passed through at a rate of 2,000 m ³ /h 94 percent of the carbon dioxide contained in the airflow was removed and approx. 1 kg of CO2 was separated within 20 minutes. reference list

10 systems

11 air inlet

12 dehumidification unit

13 Adsorber unit 14 Air outlet

15 desorption module

Claims

PATENT CLAIMS: Process for the utilization of carbon dioxide contained in the ambient air, comprising the drying of an ambient air flow in a dehumidification unit (12) and then the adsorption of carbon dioxide from the dried air flow in an adsorber unit (13), which contains an adsorber material for CO2, and then the Desorption of adsorbed carbon dioxide from the adsorber unit (13), the adsorption of carbon dioxide being carried out until a termination criterion is reached, and then the desorption of carbon dioxide taking place, characterized in that the drying of the ambient air flow takes place in a two-stage process which a pre-drying of the air flow in a continuously operating electrically operated pre-dryer, which is a continuously operating adsorption dryer, and a subsequent passage of the pre-dried air flow through a drying device filled with a drying agent comprising silica gel, molecular sieve 3A, sodium sulfate, magnesium sulfate, activated aluminum oxide or zeolite A, that the adsorption of carbon dioxide from the dried air stream takes place at normal pressure and a temperature in the range from 20°C to 35°C, and that for the desorption of adsorbed carbon dioxide from the adsorber unit (13) the adsorber material in the adsorber unit (13) to a temperature heated in the range of 100 ° C to 300 ° C and in the adsorber unit (13) a negative pressure in the range of 10 to 50 mbar is generated. Method according to claim 1, wherein the termination criterion is reaching the capacity limit of the adsorber material for the adsorption of CO2. Method according to Claim 1, in which the termination criterion is the expiry of a predetermined period of time. A method according to any one of claims 1 to 3, wherein the adsorbent material for CO2 comprises amorphous aluminum silicate. 5. The method according to any one of the preceding claims, in which the residual moisture content of the air flow after drying is less than 1 g/m ³ .

6. System (10) for recycling carbon dioxide from the ambient air, which has an inflow opening (11) which is fluidically connected to an outlet opening (14) which has a blower or a fan, so that an air duct is formed and air out is drawn in from the environment and passed through a dehumidification unit (12) and an adsorber unit (13), the dehumidification unit (12) being set up to dry an ambient air flow supplied to the system (10), and the adsorber unit (13) being set up for this is to bind carbon dioxide from the dried ambient air flow during an adsorption phase and to release bound carbon dioxide during a desorption phase, and wherein the system (10) comprises a desorption module (15) which is set up in the adsorber unit (13) to absorb carbon dioxide adsorbed therefrom desorb, and comprises heating means to introduce heat into the adsorber unit (13) during the desorption phase, and vacuum means to generate a vacuum in the adsorber unit (13) during the desorption phase, wherein the dehumidification unit (12) has a continuously operating electrically operated Pre-dryer, which is a continuously operating adsorption dryer, and comprises a drying device downstream of this, which is filled with a desiccant which comprises silica gel, molecular sieve 3A, sodium sulfate, magnesium sulfate, activated alumina or zeolite A.

7. System (10) according to claim 6, wherein a CO2 sensor is arranged at the outlet of the adsorber unit (13), which measures the CC content of the exiting gas stream.

8. System (10) according to claim 6 or 7, wherein the adsorber unit (13) contains amorphous aluminum silicate as adsorber material for CO2.<