DE102022203471A1 - CO2 adsorption device for separating CO2 (carbon dioxide) from air - Google Patents

Abstract

A CO2 adsorption device (10) is proposed for separating CO2 from an air stream (12) supplied, in particular by means of a fan unit, by means of a cyclically carried out adsorption-desorption process, with an adsorption chamber (14), in the interior (20) of which an air-permeable separating element (22) is arranged, the interior (20) being separated by means of the air-permeable separating element (22) into an injection chamber (24), into which the air flow (12) can be fed via an inlet opening (16), and into an adsorbent chamber ( 26), from which the CO2-reduced air flow (12`) can be removed by means of an outlet opening (18), is divided, with a loosely arranged bed (28) of CO2 adsorption bodies (30) and a heating unit in the adsorbent chamber (26). (32) are arranged for heating the bed (28) of CO2 adsorption bodies (30), wherein in intended use the adsorbent chamber (26) is arranged above the injection chamber (24), so that the loosely arranged bed (28) of CO2 Adsorption bodies (30) are arranged resting on the air-permeable separating element (22).

Description

State of the art

The invention relates to a CO2 adsorption device for separating CO2 (carbon dioxide) from an air stream supplied, in particular by means of a fan unit, by means of a cyclically carried out adsorption-desorption process, a CO2 adsorption system with such a CO2 adsorption device and a method for introducing and /or discharging a bed of CO2 adsorption bodies into a CO2 adsorption device.

In order to limit the warming of the earth's atmosphere, it is being discussed to actively reduce the CO2 content that has increased due to industrialization. For this purpose, so-called “direct air capture” systems (DAC) can also be used, which actively remove and concentrate CO2 from the ambient air outdoors in a first system or via the ventilation system in buildings, for example, so that the CO2 is then released into a second system can be permanently bound, e.g. by pressing into geological cavities.

The WO 2014/170184 A1 and the WO 2015/185434 A1 disclose such a first system, in which CO2 from the air in a first system is temporarily bound to an adsorber medium (adsorption) by conveying it using a fan (adsorption), so that in a second step after closing the unit from the environment, the CO2 from Adsorber medium can be removed again and fed to the second system via pipelines (desorption). Here, adsorption, as is familiar to a person skilled in the art, is carried out under different physical conditions than desorption. This means, for example, adsorption takes place at 25°C, 1013 mbar and a relative humidity of 50% RH, and desorption takes place at 80°C and 200 mbar.

In order to be able to carry out desorption at an elevated temperature on the adsorbent, the adsorbent must be heated. The adsorbents degenerate at elevated temperatures, so everything should be cooled down quickly afterwards.

Cost-effective heating can be achieved, for example, using existing heat flows that are coupled from neighboring systems to the first system using fluid-conducting temperature control lines, but the disadvantage is that heat exchangers, pumps, valves, sensors and pipes have to be used for this and the adsorbent has to be heated by means of a e.g. heating coil register (the adsorbent is arranged around the heating coils), so that these devices require high investment costs, but above all have a high heat capacity (weight of the stainless steel used for pipes, etc.).

Since the adsorbent can only absorb CO2 again after cooling, the system must be cooled back to almost ambient temperature after desorption for effective operation. Cooling with ambient air takes a comparatively long time in known systems due to the high heat capacity, so that the adsorbent also degenerates unnecessarily. Active cooling has to cool down the heating system described above with cooling water and requires additional pumps and heat exchangers, etc., so that the overall system of the first system becomes more complex and therefore less self-sufficient.

Using a heat pump, the external thermal energy required at a high temperature level for desorption and/or at a low temperature level for cooling can be significantly reduced, but the energy requirement then shifts to an electrical energy requirement for the heat pump, whereas the effort and costs for piping, valves, Pumps and heat exchangers are likely to become even larger.

If it is necessary to change the adsorbent in a system in accordance with the previously mentioned publications, the heat transfer fluid must be emptied from the fluid-heated register (heating coils). Then the lines are separated, the register removed, the adsorber replaced, the register reinstalled and the fluid connections reconnected.

Ultimately, the fluid lines must be checked for leaks before the system can be refilled. Forecasted systems consist of > > 1000 initial systems, each with >10 supports, which have to be renewed regularly.

Disclosure of the invention

The subject of the present invention is a CO2 adsorption device for separating CO2 (carbon dioxide) from an air stream supplied, in particular by means of a fan unit, by means of a cyclically feasible adsorption-desorption process, with an adsorption chamber, in the interior of which an air-permeable separating element is arranged, whereby the interior is divided by means of the air-permeable separating element into an injection chamber, into which the air flow can be fed via an inlet opening, and into an adsorbent chamber, from which the CO2-reduced air flow can be removed via an outlet opening, with a loosely arranged bed of in the adsorbent chamber CO2 adsorption bodies and an expansion mung unit for heating the bed of CO2 adsorption bodies are arranged, wherein in intended use the adsorbent chamber is arranged above the injection chamber, so that the loosely arranged bed of CO2 adsorption bodies is arranged resting on the air-permeable separating element.

The present invention further relates to a CO2 adsorption system with a CO2 adsorption device according to the type described above and a control unit for controlling the heating unit for the adsorption-desorption process.

The present invention also relates to a method for introducing and/or discharging a bed of CO2 adsorption bodies into a CO2 adsorption device according to the type described above or into a CO2 adsorption system according to the type described above for separating CO2 (carbon dioxide) from one , in particular by means of a fan unit, air flow supplied by means of a cyclically carried out adsorption-desorption process, the bed of CO2 adsorption bodies being blown into and/or sucked out of the CO2 adsorption device via the outlet opening and/or the adsorbent opening of the adsorption chamber of the CO2 adsorption device.

The CO2 adsorption device according to the invention now makes it possible to use very simple and efficient large-scale approaches to CO2 capture, such as horizontal tanks or containers or (ISO) containers, which have significant cost reduction potential by scaling the size instead of parallelization enable complex systems. In addition, the CO2 adsorption device according to the invention allows very simple introduction and replacement of the CO2 adsorption material and, if necessary, the heating unit, which means that there is significantly less maintenance effort.

The basic functionality of the CO2 adsorption device can be analogous to the device described in the introduction WO 2015/185434 A1 take place.

In the context of the present invention, the term “separation” includes a separation, for example separation, of CO2 from the air.

In the context of the present invention, the term “supply” or “supplied” includes both an actively carried out or induced and a passively carried out or induced supply of the air flow. Consequently, the air flow can be technically controlled or regulated, for example by means of a fan unit, but also supplied in a natural way.

The adsorption chamber can be designed as a horizontally aligned circular cylinder, in particular a horizontal tank or container, or as a cuboid, in particular a container, preferably an ISO container. The diameter or the height and the length of the adsorption chamber are understandably adapted to the application or the air requirement. For example, the diameter or height can be 4 to 5 m and the length of the adsorption chamber can be, for example, 10 to 20 m. However, the adsorption device can also be integrated into an air conditioning system, for example, so that the diameter or the height and the length of the adsorption chamber can be correspondingly smaller.

An air-permeable separating element is arranged inside the adsorption chamber, which divides the interior into an injection chamber, i.e. an injection area, and an adsorbent chamber, i.e. an adsorbent area. In other words, the adsorption chamber has two sub-chambers or areas which are separated by means of the air-permeable separating element. Due to the air permeability of the separating element, the injection chamber and the adsorbent chamber are fluidly connected to one another. The air-permeable separating element can, for example, be designed in the form of a grid or plate.

Since the bed of CO2 adsorption bodies rests on the air-permeable separating element and the separating element is therefore in heat-transferring contact with the CO2 adsorption bodies, the air-permeable separating element can advantageously be designed to be heatable, i.e. directly heatable, in order to prepare the bed of CO2 adsorption bodies for the desorption process heat. Here, the air-permeable separating element can preferably be designed to be electrically heatable and, in particular, have corresponding electrical connections for this purpose. The air-permeable separating element can have an electrically conductive polymer or an electrically conductive polymer composite material for electrical heatability. With this measure, the heating of the CO2 adsorption bodies and thus the desorption process can be accelerated or optimized very easily.

The air flow can be fed into the injection chamber via an inlet opening of the adsorption chamber, from there can be guided into the adsorbent chamber via the air-permeable separating element and can then be removed from the adsorbent chamber via an outlet opening of the adsorption chamber. The injection chamber, the adsorbent chamber and the air-permeable separator arranged between them ment are designed in such a way that the air flow supplied from the injection chamber can be guided essentially homogeneously or evenly into the adsorbent chamber and thus through the bed of CO2 adsorption bodies. Accordingly, the injection chamber is used together with the air-permeable separating element to guide the air flow homogeneously or evenly through the bed of CO2 adsorption bodies in order to achieve optimized CO2 adsorption.

The inlet opening is preferably arranged on a top or a lateral outside of the adsorption chamber. The outlet opening is preferably arranged on an underside or a lateral outside of the adsorption chamber. The outlet opening can be designed as a manhole, for example for assembly or maintenance purposes. The outlet opening can be designed in such a way that the bed of CO2 adsorption bodies can be introduced into the adsorbent chamber, in particular blown in, and/or can be removed from the adsorbent chamber, in particular blown out.

Alternatively or additionally, at least one adsorbent opening can be provided on the adsorption chamber, by means of which the bed of CO2 adsorption bodies can be introduced into the adsorbent chamber, in particular blown in, and / or can be discharged from the adsorbent chamber, in particular blown out. The at least one adsorbent opening can be arranged on a top or a lateral outside of the adsorption chamber.

The heating unit is designed to heat the bed of CO2 adsorption bodies in order to specifically release adsorbed CO2 again, i.e. to initiate or accelerate the desorption process. Here, the heating unit is preferably in heat-transferring contact with the bed of CO2 adsorption bodies.

Here, the heating unit preferably has at least one heatable heating body. More preferably, the heating unit has a plurality of heatable heating bodies, between which the loose bed of CO2 adsorption bodies is arranged in heat-transferring contact with them. The at least one heatable heating body can be selected from the group consisting of: heating grid, heating plate, heating coil, heating tube, heating rod.

It is advantageous if the at least one heatable heating body is designed to be electrically heatable, in particular having corresponding electrical connections for this purpose.

The ability to heat the heating body electrically offers a number of advantages over, for example, the fluid-conducting or water-conducting temperature control lines according to the prior art described in the introduction.

On the one hand, the electrically heated heating body offers a much more dynamic temperature profile, since parts or bodies with a high heat capacity, such as water, robust lines, connecting pieces, T-pieces, and possibly heat exchangers, are eliminated, so that the electrically heated heating body heats up faster can heat up and cool down again. In particular, an existing fan unit is sufficient to quickly cool down the CO2 adsorption bodies, since no large heat capacities have a dampening effect. This enables the desired faster changes between desorption and adsorption, which can increase overall efficiency and reduce energy requirements.

On the other hand, the complexity of the CO2 adsorption device also decreases significantly, since no heat exchangers are necessary and there may also be no need for active cooling after thermal desorption, e.g. in temperate climate zones. This also results in lower maintenance costs and better suitability for self-sufficient installation with little maintenance effort.

Due to the reduced damping mass, the electricity requirement for the desorption phase is comparable to the requirement of a heat pump that heats a heat transfer fluid for the desorption phase.

It is also advantageous if the at least one heatable heating body has an electrically conductive polymer (heat inducing thermoplastics, HiT) or an electrically conductive polymer composite material for electrical heatability. Here, the electrically conductive polymer composite material can have a polymer, in particular an electrically non-conductive polymer, and electrically conductive particles. The electrically conductive polymer or the polymer composite material is very suitable for the heating body because it heats up quickly due to the high electrical resistance and cools down quickly due to the low heat capacity and is also robust and has good chemical resistance. It is particularly advantageous that a maximum temperature can be set for these composite materials, i.e. the heating is self-limiting, so that temperatures that are too high can be reliably avoided. Since the thermal expansion of the polymer causes the conductive components to move away from each other when heated, the resistance increases as the temperature increases.

Advantageously, the at least one heatable heating body can be designed to be air-permeable, in particular grid-shaped or perforated plate-shaped or perforated, so that the supplied air flow can flow through it largely unhindered.

The at least one heatable heating body can be designed to be pluggable in the interior of the adsorption chamber and/or to be inserted into the interior of the adsorption chamber from the outside.

A plurality of essentially vertically aligned heatable heating bodies, in particular air-permeable heating grids and/or air-permeable heating plates arranged parallel to one another, is preferred.

The basic functionality of the CO2 adsorption bodies can be analogous to that described in the introduction WO 2014/170184 A1 take place.

The CO2 adsorption bodies are designed or set up for use in a CO2 adsorption device in order to separate CO2 from an air stream or the air by means of a cyclically carried out adsorption-desorption process.

The loose bed of CO2 adsorption bodies is arranged in the adsorbent chamber resting on the air-permeable separating element. This is achieved, among other things, by arranging the adsorbent chamber above the injection chamber when used as intended.

The CO2 adsorption bodies are designed to be pourable or flowable. In other words, a mixture of CO2 adsorption bodies has a pourable or flowable form. Accordingly, a large number of CO2 adsorption bodies represent a bed. The bed can, for example, have a bulk density of greater than or equal to 0.1 l/100g to less than or equal to 50 l/100g, preferably greater than or equal to 1 l/100g to less than or equal to 20 l/100g, and/or a total pressure loss of less than or equal to 400 Pa, particularly preferably less than or equal to 200 Pa.

For pourability or flowability, the CO2 adsorption bodies can be spherical or pellet-shaped. In the context of the present invention, the terms spherical and ball-shaped are used essentially synonymously. The CO2 adsorption bodies can be designed as “grains”. The CO2 adsorption bodies can have an average diameter of greater than or equal to 0.5 mm to less than or equal to 5 mm, preferably greater than or equal to 1 mm to less than or equal to 2 mm. However, the CO2 adsorption bodies can also be designed as “cotton balls”. The CO2 adsorption bodies can have an average diameter of greater than or equal to 5 mm to less than or equal to 100 mm, preferably greater than or equal to 10 mm to less than or equal to 50 mm, particularly preferably greater than or equal to 15 to less than or equal to 30 mm.

The CO2 adsorption bodies can have CO2-adsorbing fibers and stabilizing fibers, which are resistant to moisture and mechanical stress and form a fiber composite with the CO2-adsorbing fibers.

The CO2-adsorbing fibers are designed to bind or filter CO2 from the air by means of adsorption. For this purpose, the CO2-adsorbing fibers can have or consist of at least one corresponding adsorbent with a CO2-binding property. The CO2-adsorbing fibers can be produced in a manner known to those skilled in the art. Accordingly, the CO2-adsorbing fibers themselves can have a CO2-binding property. Alternatively or additionally, the CO2-adsorbing fibers can be appropriately coated, impregnated or functionalized with the at least one adsorbent to achieve the CO2-binding property. The CO2-adsorbing fibers can have or consist of carrier fibers as a carrier structure without CO2-binding properties. The carrier fibers can have or consist of a base material which is selected from at least one material from the following group: resins, polymers, ceramics, zeolites, silicates, organometallic compounds, organic materials such as cellulose or activated carbon. The carrier fibers can in turn be specifically coated, impregnated or functionalized with amines, potassium carbonate or other components that are designed to chemically or physically bind CO2. The CO2-adsorbing fibers preferably have or consist of cellulose fibers functionalized with amines. It should be noted that amines can be suitably bound to cellulose, but not to the polymer fibers or synthetic fibers mentioned above.

The stabilizing fibers can in turn be designed to hold the fiber composite in a spherical shape, so that the CO2 adsorption bodies are designed to be pourable and/or flowable. In other words, instead of known CO2 adsorption mats, which consist of functionalized cellulose, a spherical or ball-shaped fiber composite with additional stabilizing fibers can be provided, which are resistant to moisture and mechanical stress and are also designed to keep the fiber composite in a spherical shape or spherical shape/ball shape - analogous to so-called “filter balls” - so that the CO2 adsorption bodies are pourable and/or flowable.

In the context of the present invention, a fiber composite is to be understood as a mechanical composite made up of the stabilizing fibers and the CO2-adsorbing fibers. The stabilizing fibers and the CO2-adsorbing fibers are preferably processed together, in particular woven together into a fabric and/or spun into a yarn, in order to form the fiber composite. Alternatively, the CO2-adsorbing fibers can be formed within the stabilizing fibers (intrinsically) due to the manufacturing process. In other words, the CO2-adsorbing fibers were formed within a stabilizing fiber structure during manufacture. This can be achieved, for example, by freeze-drying the CO2-adsorbing fibers, for example cellulose fibers, from a solution in which stabilizing fibers are already floating. Alternatively, the stabilizing fibers can form a ball-like outer network, in whose cavity the CO2-adsorbing fibers are enclosed.

The fiber composite preferably has a proportion of stabilizing fibers of between greater than or equal to 10% by mass to less than or equal to 90% by mass.

The stabilizing fibers are fibers that are different from the CO2-adsorbing fibers. It is advantageous if the stabilizing fibers are selected from the group consisting of: polymer fibers, synthetic fibers, cellulose-free natural fibers, glass fibers, mineral fibers, rock wool fibers, carbon fibers or combinations thereof. The polymer fibers and the cellulose-free natural fibers are preferably selected from the group consisting of: PE (polyethylene), PP (polypropylene), PVDF (polyvinylidene fluoride), PET (polyethylene terephthalate), wool, or mixtures thereof. Here, the polymer fibers can be made from recycled polymer fiber material, in particular from PET bottle recycling material, and/or the carbon fibers can be made from recycled carbon fiber material, in particular cut carbon fibers from recycling processes. This selection offers the advantage that these fibers or materials have the required resistance to moisture and mechanical stress and are also easy to process. Cellulose is excluded here, as it would lose the required porosity over time, particularly under high humidity and mechanical stress, and would therefore collapse and become matted. The carbon fibers also offer the advantage that they can be used to conduct electricity, so that the fill itself can be heated.

Changing the adsorption material is disproportionately complex for larger CO2 adsorption devices or systems, since the separation performance and the maintenance effort increase linearly with the separation performance. In the chemical industry, the CAPEX should only increase with larger outputs according to the average degression exponent of 2/3, i.e. if output is doubled, the effort should be on average 2^(2/3) times, i.e. 1.587 times. OPEX should only be tied to energy requirements - and personnel costs for operation and maintenance should ideally be independent of the size. The lying bed of CO2 adsorption bodies offers the great advantage that the CO2 adsorption bodies - in contrast to the CO2 adsorption mats, which are difficult to assemble in the CO2 adsorber device - are designed due to the spherical shape or spherical shape/ball shape, so that they fit into the CO2 adsorber device can be inflated and sucked out again. This significantly simplifies the exchange, i.e. insertion and removal process, of the adsorption material and therefore offers significantly less maintenance effort. Furthermore, the spherical or ball-shaped CO2 adsorption bodies offer better utilization of space compared to the CO2 adsorption mats and thus higher volume efficiency.

However, the spherical or ball-shaped CO2 adsorption bodies are subject to mechanical stresses both during operation, especially with higher fills, as well as during the blowing and suction process, to which the CO2 adsorption mats enclosed in a frame are not exposed and therefore do not have the required stability . As a result, the stabilizing fibers are resistant to moisture and mechanical stress, so that in particular the CO2 adsorption bodies collapse during operation as well as matting and thus clumping in the injection or suction pipe can be prevented.

The CO2 adsorption device can further have a valve unit, which comprises a plurality of valves and is designed to form a closed adsorption chamber for the desorption. The valve unit can have an inlet valve, which is arranged in an inlet channel fluidly connected to the inlet opening and is designed to close the inlet channel and isolate the absorption chamber upstream. The valve unit can further have an outlet valve, which is in one with the outlet opening fluidically connected outlet channel for the CO2-reduced air flow is arranged and designed to close the outlet channel and isolate the adsorption chamber downstream. The valve unit can also have a CO2 valve, which is arranged in a CO2 outlet channel and is designed to open the CO2 outlet channel in order to specifically release the adsorbed, ie bound/filtered and desorbed, ie released CO2 from the adsorption chamber.

For desorption, the CO2 adsorption device can also have a pump unit which is designed to generate a negative pressure in the adsorption chamber. Furthermore, the CO2 adsorption device can have a pressure accumulator receiving unit on the CO2 outlet channel for detachably accommodating a CO2 pressure accumulator. Since 5-50 bar CO2 pressure should be achieved for this, the pump unit can have a high-pressure pump. The pump unit can therefore have, for example, a combination of a vacuum pump with a compressor.

The CO2 adsorption system preferably has a fan unit for supplying and/or discharging the air flow, wherein the control unit is designed to further control the fan unit for the adsorption-desorption process.

The CO2 adsorption system can also have a straightening unit which is designed to straighten increases in the bed of CO2 adsorption bodies so that the height distribution of the bed in the interior of the adsorption chamber is essentially uniform. The straightening unit can be designed, for example, as a shaking unit or as a pulling unit, in particular a pulling bar.

In the process for introducing and/or removing the bed, new CO2 adsorption bodies are preferably blown in and these are sucked out again after they have degenerated due to several adsorption-desorption cycles.

drawings

• 1 eine schematische Darstellung einer erfindungsgemäßen CO2-Adsorptionsvorrichtung mit einer Schüttung von CO2-Adsorptionskörpern; und
• 2 eine perspektivische Darstellung des Innenraumes der erfindungsgemäßen CO2-Adsorptionsvorrichtung aus 1.

The invention is explained in more detail below using the accompanying drawings. Show it:

• 1 a schematic representation of a CO2 adsorption device according to the invention with a bed of CO2 adsorption bodies; and
• 2 a perspective view of the interior of the CO2 adsorption device according to the invention 1 .

1 shows a CO2 adsorption device, which is provided with the reference number 10 in its entirety.

The CO2 adsorption device 10 is designed to separate CO2 (carbon dioxide) from an air stream 12 supplied by means of a fan unit (not shown) by means of a cyclically feasible adsorption-desorption process. For this purpose, the CO2 adsorption device 10 has an adsorption chamber 14.

The adsorption chamber 14 is designed as a horizontal tank 14. The adsorption chamber 14 has an inlet opening 16 on a lateral outside for supplying the air stream 12 into the adsorption chamber 14 and an outlet opening 18 for discharging the CO2-reduced air stream 12 'from the adsorption chamber 14.

An air-permeable separating element 22 is arranged in an interior 20 of the adsorption chamber 14. The air-permeable separating element 22 is designed in the shape of a grid. The air-permeable separating element 22 divides the interior 20 of the adsorption chamber 14 into an injection chamber 24 and an adsorbent chamber 26. Due to the air permeability of the separating element 22, the injection chamber 24 and the adsorbent chamber 26 are fluidly connected to one another.

A loosely arranged bed 28 of CO2 adsorption bodies 30 and a heating unit 32 for heating the bed 28 of spherical CO2 adsorption bodies 30 are arranged in the adsorbent chamber 26. In the intended use shown, the adsorbent chamber 26 is arranged above the injection chamber 24, so that the loosely arranged bed 28 of CO2 adsorption bodies 30 is arranged resting on the air-permeable separating element 22. The heating unit 32 has a plurality of heatable heating bodies 34, between which the loose bed 28 of CO2 adsorption bodies 30 is arranged in heat-transferring contact. How out 2 As can be seen in more detail, the heatable heating bodies 34 are designed as air-permeable heating grids 34. The air-permeable heating grids 34 are aligned essentially vertically and parallel to one another. In the exemplary embodiment shown, the air-permeable heating grids 34 are designed to be electrically heatable and have corresponding electrical connections 36 for this purpose.

In a preferred embodiment, the air-permeable separating element 22 can also be designed to be heatable, in particular electrically heatable, in order to fill the bed 28 of CO2 adsorp tion bodies 30 for the desorption process.

Consequently, the air flow 12 can be fed into the injection chamber 24 via the inlet opening 16 of the adsorption chamber 14, from there via the air-permeable separating element 22 into the adsorbent chamber 26 through the bed 28 of CO2 adsorption bodies 30 and then out via an outlet opening 18 of the adsorption chamber 14 Adsorbent chamber 26 can be removed. The injection chamber 24, the adsorbent chamber 26 and the air-permeable separating element 22 arranged between them are designed in such a way that the air flow 12 supplied from the injection chamber 24 can be guided essentially homogeneously or evenly into the adsorbent chamber 26 and thus through the bed 28 of CO2 adsorption bodies 30 is to achieve optimized CO adsorption.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2014170184 A1 [0003, 0034]
• WO 2015185434 A1 [0003, 0014]

Claims (20)

CO2 adsorption device (10) for separating CO2 from an air stream (12) supplied, in particular by means of a fan unit, by means of a cyclically carried out adsorption-desorption process, with an adsorption chamber (14), in the interior (20) of which there is an air-permeable separating element ( 22), wherein the interior (20) by means of the air-permeable separating element (22) into an injection chamber (24), into which the air flow (12) can be fed via an inlet opening (16), and into an adsorbent chamber (26). the CO2-reduced air flow (12`) can be removed by means of an outlet opening (18), is divided, with a loosely arranged bed (28) of CO2 adsorption bodies (30) and a heating unit (32) in the adsorbent chamber (26). Heating the bed (28) of CO2 adsorption bodies (30) are arranged, wherein in intended use the adsorbent chamber (26) is arranged above the injection chamber (24), so that the loosely arranged bed (28) of CO2 adsorption bodies (30) is arranged resting on the air-permeable separating element (22). CO2 adsorption device (10). Claim 1 , characterized in that the heating unit (32) is in heat-transferring contact with the bed (28) of CO2 adsorption bodies (30). CO2 adsorption device (10). Claim 1 or 2 , characterized in that the heating unit (32) has at least one heatable heating body (34), in particular a plurality of heatable heating bodies (34), between which the loose bed (28) of CO2 adsorption bodies (30) is arranged in heat-transferring contact. CO2 adsorption device (10) according to 3, characterized in that the at least one heatable heating body (34) is selected from the group consisting of: heating grid (34), heating plate, heating coil, heating tube, heating rod. CO2 adsorption device (10). Claim 3 or 4 , characterized in that the at least one heatable heating body (34) is designed to be air-permeable, in particular grid-shaped or perforated plate-shaped or perforated. CO2 adsorption device (10) according to one of the Claims 3 until 5 , characterized in that the at least one heatable heating body (34) is designed to be pluggable in the interior (20) of the adsorption chamber (14) and / or insertable from the outside into the interior (20) of the adsorption chamber (14). CO2 adsorption device (10) according to one of the Claims 3 until 6 , characterized by a plurality of essentially vertically aligned heatable heating bodies (34), in particular air-permeable heating grids (34) and / or air-permeable heating plates arranged parallel to one another. CO2 adsorption device (10) according to one of the preceding claims, characterized in that the air-permeable separating element (22) is designed in the form of a grid or plate. CO2 adsorption device (10) according to one of the preceding claims, characterized in that the air-permeable separating element (22) is also designed to be heatable in order to heat the bed (28) of CO2 adsorption bodies (30) for the desorption process. CO2 adsorption device (10) according to one of the preceding claims, characterized in that the at least one heatable heating body (34) and/or the air-permeable separating element (22) is/are designed to be electrically heatable, in particular having corresponding electrical connections (36) for this purpose. CO2 adsorption device (10). Claim 10 , characterized in that the at least one heatable heating body (34) and / or the air-permeable separating element (22) has / have an electrically conductive polymer or an electrically conductive polymer composite material for electrical heatability. CO2 adsorption device (10) according to one of the preceding claims, characterized in that the adsorption chamber (14) is designed as a horizontally aligned circular cylinder (14), in particular a lying tank (14) or as a cuboid, in particular a container, preferably an ISO container. CO2 adsorption device (10) according to one of the preceding claims, characterized in that the outlet opening (18) is designed as a manhole. CO2 adsorption device (10) according to one of the preceding claims, characterized by at least one adsorbent opening, by means of which the bed (28) of CO2 adsorption bodies (30) can be introduced into the adsorbent chamber (26), in particular blown in, and / or from the Adsorbent chamber (26) can be deployed, in particular blown out. CO2 adsorption device (10) according to one of the preceding claims, characterized in that - the inlet opening (16) is arranged on a top or a lateral outside of the adsorption chamber (14); and/or - the outlet opening (18) is arranged on an underside or a lateral outside of the adsorption chamber (14); and/or - the at least one adsorbent opening is arranged on an upper side or a lateral outside of the adsorption chamber (14). CO2 adsorption device (10) according to one of the preceding claims, characterized in that the CO2 adsorption bodies (30) are spherical or pellet-shaped. CO2 adsorption system with a CO2 adsorption device (10) according to one of the preceding claims and a control unit for controlling the heating unit (32) for the adsorption-desorption process. CO2 adsorption system Claim 17 , characterized by a fan unit for supplying and/or discharging the air flow (12, 12`), the control unit being designed to further control the fan unit for the adsorption-desorption process. CO2 adsorption system Claim 17 or 18 , characterized by a straightening unit which is designed to straighten increases in the bed (28) of CO2 adsorption bodies (30), so that the height distribution of the bed (28) in the interior (20) of the adsorption chamber (14) is essentially uniform. Method (100) for introducing and/or discharging a bed (28) of CO2 adsorption bodies (30) into a CO2 adsorption device (10) according to one of Claims 1 until 16 or into a CO2 adsorption system Claim 17 or 18 for separating CO2 from an air stream (12) supplied, in particular by means of a fan unit, by means of a cyclically carried out adsorption-desorption process, wherein the bed (28) of CO2 adsorption bodies (30) via the outlet opening (18) and / or the Adsorbent opening of the adsorption chamber (14) of the CO2 adsorption device (10) is blown into it and / or sucked out of it.

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