DE202021100879U1 - Direct air capturing device - Google Patents

Abstract

Direct air capturing (DAC) device (10), the DAC device (10) being designed to extract carbon dioxide from air, characterized in that the DAC device (10) can be arranged on a ship, the DAC The device (10) is designed to absorb air that is moved relative to the DAC device (10) when the ship is moving and to obtain carbon dioxide from it.

Description

The invention relates to a direct air capturing device according to claim 1.

State of the art

Direct Air Capturing (DAC) is a promising way of extracting carbon dioxide (CO ₂ ) from ambient air. Since CO ₂ only accounts for 0.04% in the air mixture, the yield is either low, while the energy required to enrich the air with a fan, for example, is high. Large fans are therefore required to extract carbon dioxide in order to “push” the ambient air through a corresponding DAC device. One of the biggest hurdles in the implementation of DAC devices is therefore the cost, which is significant with regard to the corresponding fans.

Presentation of the invention: task, solution, advantages

The present invention is based on the object of providing a DAC device in which the energy efficiency of carbon dioxide production is significantly increased.

The aforementioned object is achieved by a DAC device which is designed to extract carbon dioxide from air, the DAC device being designed to be able to be arranged on a ship. The DAC device is preferably arranged on a ship. "Air" means ambient air. The DAC device is designed to take in air which moves relative to the DAC device due to a movement of the ship, in order to obtain carbon dioxide from this air.

In particular, the DAC device does not include a device for drawing in air, preferably no fan. The DAC device is thus designed to use exclusively air, which moves relative to the DAC device due to a movement of the ship, for the production of carbon dioxide. This significantly increases the energy efficiency of the carbon dioxide production, since the considerable amount of energy required to operate the corresponding fan is not incurred. Instead of moving air towards the DAC device by means of a fan, as proposed in the prior art, in the present case the DAC device is, so to speak, moved towards the air. Carbon dioxide can thus be obtained much more cheaply.

In particular, the DAC device can have a door, preferably a sliding door. Furthermore, the DAC device can comprise at least one slat blind. The air flow can be dosed through a slat blind.

In particular, the door is arranged on a first end face of the DAC device. The door is used to lock and thus protect the device in adverse weather. Furthermore, the DAC device can comprise a protective grille. The protective grille is arranged in particular behind the sliding door in the direction of flow and serves to prevent large parts from getting into a receiving area of the DAC device. The DAC device also includes a receiving area, which is designed in particular as a tunnel, and preferably extends from the first end face to the second end face of the DAC device. A first slat blind is also preferably arranged on the first end face.

The DAC device can preferably be arranged in a container. This can be a 40-foot container, but the container can also be made lower or narrower.

The DAC device is aligned in particular in such a way that air moved by the ship's movement flows into the receiving area of the DAC device. In other words, the first end face, which includes the door, points in the direction of travel of the ship. Air can escape again at the second face.

The DAC device preferably further comprises at least one spray device for spraying the air that has been taken in with a liquid that binds carbon dioxide. The spray device can form a spray of the carbon dioxide-binding liquid and spray the air with it. The carbon dioxide-binding liquid can in particular be an alkali. In particular, it is a hydroxide solution.

The liquid can be calcium hydroxide, caustic soda or potassium hydroxide. The liquid is a carbon dioxide absorber that reacts with carbon dioxide to form a corresponding carbonate. The carbon dioxide is stored in particular as carbonate. Ultimately, storage as carbonate is advantageous because it takes up less space than the gaseous carbon dioxide. The carbonate can also be an important raw material. In particular, sodium carbonate is in great demand, so that sodium hydroxide is preferred as the liquid. Sodium carbonate can be used, for example, as a flux, bleaching agent, desulphurizing agent and for processing waste paper. Furthermore, carbonate can be used as a carbonate fertilizer in agriculture, can be used, for example, as a carbon dioxide donor in greenhouses and / or as an addition to nutrient media for the cultivation of microalgae. In order to release high-purity gaseous carbon dioxide from the carbonate, it can be heated.

In particular, the DAC device comprises at least one central spray device and / or at least one circular spray device. The circular spray device can in particular be arranged on and / or in a tunnel wall which delimits the tunnel. For this purpose, the tunnel wall can have several openings for discharging liquid. The air in the tunnel is thus sprayed with the carbon dioxide-binding liquid from the tunnel wall. A central spray device is arranged, in particular, in the middle of the tunnel. In particular, the central spray device extends at a central point in the tunnel in the longitudinal direction of the tunnel and has a plurality of openings in order to spray liquid in different directions.

In addition or as an alternative to the spray device, a drip device can also be used. The drip device is used to generate drops of carbon dioxide-binding liquid and to drip them into the air. The droplets can be dispensed from several tubes arranged horizontally one above the other and one behind the other with regularly attached openings.

Furthermore, the DAC device comprises at least one droplet separator for separating the spray mist and / or the droplets and a collecting basin for collecting separated liquid. The collecting basin can preferably comprise a check valve. The separated spray mist and / or the separated drops can be passed on from the collecting basin into a harvesting container, whereby these form a liquid which contains the resulting carbonate. The harvest container can be arranged outside or inside the container. Furthermore, the DAC device can comprise a storage container for the carbon dioxide-binding liquid, which can be arranged outside or inside the container. An arrangement outside is advantageous, since these can then be easily exchanged. The storage container and the harvesting container are connected to the DAC device in such a way that liquid is removed from the storage container for spraying the air and liquid containing carbonate is fed to the harvesting container. Optionally, the DAC device could comprise a pump with which liquid can be pumped again in the direction of the spray device in order to use it again for spraying the air and / or for forming droplets. This could be done depending on the degree of saturation of the solution. For this purpose, the DAC device could comprise a unit for evaluating the degree of saturation and controlling the pump.

The cross section of the tunnel can increase starting from the first end face. The tunnel can preferably comprise a first area for spraying the air, wherein the tunnel in this area can have a constant, preferably round, cross-section. Furthermore, the tunnel can comprise a second area which is used to separate the spray mist and / or the droplets. The spray and / or drip device is arranged in the first area, while the droplet separator is arranged in the second area. The second area should be long enough to separate all of the liquid.

Here the tunnel can have a larger cross-section, and the shape can also change, for example from a round cross-section to a larger, rectangular cross-section. An increase in the cross section serves to reduce the flow velocity of the air below a threshold value, for example below a value of 10 m / s. Furthermore, a second lamellae can be arranged at the end of the second area, in other words the droplet separator zone. In cooperation with the first slat blind on the first front side, the dwell time of the air flow in the DAC device can be regulated. The effectiveness of the spray or drip device and the droplet separator is determined by their length and their relationship to one another.

Figure list

• 1: eine erfindungsgemäße DAC-Vorrichtung.

It shows purely schematically:

• 1 : a DAC device according to the invention.

Preferred embodiment of the invention

In 1 is a DAC device according to the invention 10 shown in a longitudinal section.

The DAC device 10 has a first end face 12th and a second face 13th on. On the first face 12th are a sliding door 14th for closing the DAC device and a protective grille 15th arranged. Furthermore, is on the first face 12th a first slat blind 25th arranged.

The DAC device 10 further comprises a receiving area 16 for taking in air moved by the movement of the ship on which the DAC device is located, the receiving area 16 as a tunnel 17th is trained. The tunnel 17th extends from the first end face 12th to the second face 13th . The tunnel 17th is through the tunnel wall 18th limited. The tunnel 17th initially has a circular cross-section, while it has a cross-sectional widening approximately in the central region 19th includes to slow down the air flowing through.

In particular, the tunnel 17th in a first area 17a and a second area 17b be subdivided. In a first area 17a there are two spray devices 20th , namely a central spray device 21 and a circular sprayer 22nd that are in the tunnel wall 18th is arranged. The central spray device 21 is central in the tunnel 17th arranged and is with fastening bars on the tunnel wall 18th attached. In the first area 17a inflowing air is sprayed with a carbon dioxide-binding liquid both from the central side and from the tunnel wall. In addition to the spray device, drops can also be generated from horizontally extending pipes.

In a second area 17b there is a droplet separator, which is in 1 is only indicated purely schematically, so that the spray mist can be deposited. In the second area 17b is the lower tunnel wall 18th designed in such a way that its height in the longitudinal section in the direction of the second end face 13th decreases. An inclined plane is thus formed, at least as far as a drain 24 to a sump and then on to a harvest bin.

The first area 17a of the tunnel 17th should be so long that the amount of spray or the amount of drops is sufficient to bind the carbon dioxide in the entire air flowing through. The second zone 17b should be long enough that all liquid can be separated. There is also the end of the second area 17b , in other words at the second front end 13th , a second venetian blind 26th .

List of reference symbols

10

DAC device

12th

first face

13th

second face

14th

sliding door

15th

Protective grille

16

Recording area

17th

tunnel

17a

first area

17b

second area

18th

Tunnel wall

19th

Cross-sectional expansion

20th

Spray device

21

central spray device

22nd

circular spray device

23

Droplet eliminator

24

Drain

25th

first louvre blind

26th

second venetian blind

Claims (16)

Direct air capturing (DAC) device (10), the DAC device (10) being designed to extract carbon dioxide from air, characterized in that the DAC device (10) can be arranged on a ship, the DAC The device (10) is designed to absorb air that is moved relative to the DAC device (10) when the ship is moving and to obtain carbon dioxide from it. DAC device (10) Claim 1 , characterized in that the DAC device (10) does not include a device for drawing in air DAC device according to one of the preceding claims, characterized in that the DAC device (10) does not comprise a fan. DAC device (10) according to one of the preceding claims, characterized in that the DAC device (10) is arranged in a container. DAC device (10) according to one of the preceding claims, characterized in that the DAC device (10) comprises a tunnel (17) as a receiving area (16) for receiving and forwarding the air. DAC device (10) according to one of the preceding claims, characterized in that the DAC device (10) has a door. DAC device (10) according to one of the preceding claims, characterized in that the DAC device (10) comprises a protective grille (15). DAC device (10) according to one of the preceding claims, characterized in that the DAC device (10) comprises at least one slatted blind (25), the DAC device preferably having a first slatted blind (25) on a first end face (12) includes. DAC device (10) according to one of the preceding claims, characterized in that the DAC device (10) comprises at least one drop device for generating drops from a carbon dioxide-binding liquid and for dripping the air with the drops. DAC device (10) according to one of the preceding claims, characterized in that the DAC device (10) has at least one spray device (20) for generating a spray mist from a carbon dioxide-binding liquid and for spraying the air with the spray mist. DAC device (10) Claim 10 , characterized in that the DAC device (10) comprises a central spray device (21) and / or a circular spray device (22). DAC device (10) Claim 9 to 11 , characterized in that the DAC device (10) comprises at least one droplet separator (23) for separating the spray mist and / or the droplets. DAC device (10) Claim 5 and one of the Claims 8 to 12th , characterized in that the tunnel (17) comprises a first area (17a) for spraying and / or dripping the air and a second area (17b) for separating the spray mist and / or the droplets, the DAC device (10) a second louvre blind (26), and wherein the second louvre blind (26) is arranged at the end of the second region (17b). DAC device (10) Claim 12 , characterized in that the DAC device (10) comprises a collecting basin for collecting separated spray mist and / or separated droplets. DAC device (10) according to one of the Claims 9 to 14th , characterized in that the DAC device (10) comprises a storage container for the carbon dioxide-binding liquid, the storage container being arranged outside or inside the container. DAC device (10) according to one of the Claims 14 or 15th , characterized in that the DAC device (10) comprises a harvesting container for receiving the liquid formed in the collecting basin, the harvesting container being arranged outside or inside the container.

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