Patent Description:
Gaseous components such as carbon dioxide, methane or sulfur dioxide make a substantial contribution to air pollution.

In particular the rising CO<NUM> concentration in the atmosphere increased the demand for research into CO<NUM> mitigation technologies. Carbon capture utilization and sequestration strategies have focused so far on capturing CO<NUM> from point sources such as coal-fired power plants, or natural gas (NG) production wells. However, stationary sources account for only one-third of global emissions. In addition, transportation costs arise when transporting the generated CO<NUM> from the point sources to plants in order to further process the generated CO<NUM>.

Another strategy to capture CO<NUM> is directly from the air, often termed direct air capture (DAC). Carbon dioxide capture is achieved when atmospheric air makes contact with chemical media, typically an aqueous alkaline solvent or sorbents and is bound thereto. The chemical media is subsequently stripped of CO<NUM> through the application of energy (namely heat), resulting in CO<NUM> that can undergo dehydration and compression, while for example regenerating the chemical media for reuse at the same time.

Typically two main DAC systems are used for the capture of CO<NUM>, namely a high temperature (HT) aqueous solution and a low temperature (LT) solid sorbent. The present invention focuses on the low temperature (LT) solid sorbent which is explained in the following.

Typically, technologies regarding the low temperature (LT) solid sorbent use a reactor comprising the sorbent, where adsorption and desorption (regeneration) happen one after another in cycles. In the first step the reactor is open. Atmospheric air goes through the reactor naturally or with the help of fans. At ambient temperature, CO<NUM> chemically binds to the sorbent and CO<NUM> depleted air leaves the system. This step is completed when the sorbent is fully saturated with CO<NUM>. In the next step, the fans are switched off, the inlet opening of the reactor is closed and the remaining air is optionally swept out through a pressure drop by vacuuming or inserting steam into the reactor. Then, regeneration happens by heating the reactor to a certain temperature, depending on the sorbent. Released CO<NUM> is collected and transported out of the reactor for purification, compression or utilization. In order to start another cycle, the reactor is usually cooled down to ambient conditions. The sorbent determines the specific conditions of the cycles. Several different sorbents were proposed in literature, such as amines, amino-polymers, silica (TRI-PE-MCM-<NUM>), potassium carbonate (K<NUM>CO<NUM>) and K<NUM>CO<NUM>/<NUM>O<NUM>.

DAC is a relatively new and innovative technology in early commercial stages, which in a long term perspective, along with conventional technologies, can help humankind to control and mitigate climate change. At present the cost for the production of CO<NUM> using a low temperature (LT) solid sorbent are rather high.

For example <CIT> discloses a vacuum chamber for a direct air capture process enclosing an interior space for housing an adsorber structure. The vacuum chamber comprises a contiguous circumferential wall structure forming a rectangular or square chamber. The wall structure is closed in an axial direction by an inlet and an outlet axial wall, respectively, each having large circular openings. Both axial walls comprise at least one closing circular stainless steel lid allowing for, in an open position, gas to be circulated through the vacuum chamber for passing an adsorber structure. In a closed position, the lid is adapted to close the interior space and to allow evacuation of the interior space down to pressure of <NUM> mbarabs or less. In particular the transition from the circular openings in the axial walls to the rectangular or square chamber leads to a comparatively low efficiency of the vacuum chamber as a result of a relatively high flow resistance.

<CIT> discloses a gas separation unit for the separation of a first gas from a mixture by using a cyclic adsorption/desorption process using a loose particulate sorbent material for gas adsorption. The gas separation unit comprises a rectangular stack of multiple layers which each hold sorbent material. In one embodiment two adjacent stacked layers are arranged, such that gas inlet and outlet channels between the sorbent material layers have a triangular cross section. The rectangular geometry of the stack can also be optimized in terms of efficiency.

It is therefore an object of the present invention to provide an adsorber structure and a reactor comprising the adsorber structure with an improved efficiency and an increased output quantity of a gaseous component captured from atmospheric air.

The object is achieved with the adsorber structure as defined in present claim <NUM>. Preferred embodiments are illustrated in the appending sub-claims <NUM> to <NUM>.

According to the invention, there is provided an adsorber structure for capturing gaseous components such as carbon dioxide, methane or sulfur dioxide from a gas mixture. The adsorber structure comprises a cylindrical center portion extending along a longitudinal axis from a first end to a second end, a first star shaped holder arranged at the first end, and a second star shaped holder arranged at the second end of the center portion. Each of the star shaped holders comprises the same number of multiple arms which extend at a constant angular distance from the center portion in different radial outward directions. The star shaped holders are rotated relative to one another such that each arm of the first star shaped holder is positioned between two adjacent arms of the second star shaped holder when looking along the longitudinal axis from the first end toward the second end of the center portion. In other words: The star shaped holders are rotated relative to one another such that each arm of the first star shaped holder is positioned between two adjacent arms of the second star shaped holder when projecting both star shaped holders into one single plane which extends transversely to the longitudinal axis of the center portion. The adsorber structure further comprises sorbent elements for adsorbing the gaseous components such as carbon dioxide, methane or sulfur dioxide from the gas mixture. Two sorbent elements extend from each arm of the first star shaped holder to the respective two adjacent arms of the second star shaped holder along the longitudinal axis of the center portion. A gap between adjacent sorbent elements extending from two circumferentially adjacent arms of the first star shaped holder tapers towards the corresponding arm of the second star shaped holder such that a gas mixture streaming from the first end to the second end of the center portion penetrates the adjacent sorbent elements.

As the sorbent elements extend over the total length of the center portion from the first end to the second end and as adjacent sorbent elements extending from two circumferentially adjacent arms of the first star shaped holder form a tapering gap, the adsorber structure provides an optimized adsorbing surface. Moreover, as the gap between adjacent adsorber elements tapers from the first end towards the second end of the center portion and thus tapers in the flow direction of a gas mixture streaming into the adsorber structure, a uniform wetting of the sorbent elements by the gas mixture is ensured.

In an embodiment of the invention the adsorber structure further comprises connecting members extending from each arm of the first star shaped holder to the respective two adjacent arms of the second star shaped holder. Each of the connecting members, the corresponding arm of the first star shaped holder and one of the respective two adjacent arms of the second star shaped holder form a frame for supporting the sorbent elements. The frame provides a modular construction of the adsorber structure. The sorbent elements can be easily inserted in and removed from the frame. This allows an easy maintenance of the adsorber structure and the sorbent elements. The frame allows an installation of different sorbent elements comprising e.g. different sorbent materials as long as the sorbent elements comprise the geometric dimensions of the frame. The sorbent elements containing a particular sorbent material are preferably chosen depending on the gaseous component to be capture from the atmospheric air. For example the frame is capable to receive first sorbent elements containing a first sorbent material which is suitable to capture carbon dioxide from the atmospheric air. Preferably, the frame may also be capable to alternatively receive second sorbent elements containing a second sorbent material which is suitable to capture methane or sulfur dioxide from the atmospheric air. Preferably, the sorbent elements are formed by at least one sorbent module comprising a metallic structure which forms a receiving portion for receiving sorbent material in the form of bulk material. Alternatively, the sorbent modules may also be formed by a self-supporting structure such as textile structures or structures made from a plastic material which contain the sorbent material. Optionally, each of the connecting members encloses an angle with a corresponding plane extending along the longitudinal axis of the center portion and the corresponding arm of the first star shaped holder to which the connecting member connects. The angle lies in the range of about <NUM>° to <NUM>°, preferably in the range of about <NUM>° to <NUM>°, more preferably is about <NUM>°. The angle between the connecting elements and the corresponding plane correspond to a number of arms of the first star shaped holder. For example, if the angle is <NUM>° the first star shaped holder has <NUM> arms.

In another embodiment of the invention the adsorber structure is configured to be inserted into a housing of a reactor for separating gaseous components such as carbon dioxide, methane or sulfur dioxide from a gas mixture, wherein the adsorber structure is configured to support the housing of the reactor. The adsorber structure is part of the load bearing structure of the housing such that the adsorber structure supports the housing and takes loads acting on the housing. Thus, the wall thicknesses of the housing and thus the weight of the housing can be reduced. Reducing the weight of the housing also reduces the heat capacity of the housing and thus the energy needed to heat up the reactor to a temperature for regenerating the sorbent element during a desorption mode of the reactor. Optionally the housing has a cylindrical shape.

In an embodiment of the invention the adsorber structure further comprises sealing elements arranged on the connecting elements and being configured to seal the connecting elements against the inner wall of the housing. The sealing elements prohibit that the gas mixture entering the adsorber structure bypasses a sorbent element by streaming between the connecting element and the housing.

In an embodiment of the invention each sorbent element is formed by at least one sorbent module comprising two parallel oriented grid structures and sorbent material. The two grid structures are arranged at a distance from one another thereby forming a receiving portion for the sorbent material. The sorbent material is arranged between the grid structures in the receiving portion. Optionally, an amine-functionalized ion exchanger resin is used as a solid sorbent material. Preferably, the grid structures are made of metal.

In another embodiment of the invention each of the arms of the first star shaped holder and the second star shaped holder comprise a cross sectional area oriented transversely to the radial outward extension of the arms, wherein the cross sectional area of each of the arms has a triangular shape or a U-shape. A triangular or a U-shaped cross sectional area forms a flow-optimized cross section which reduces the flow resistance of the arms of the star shaped holders.

In an embodiment of the invention the arms of the first star shaped holder are oriented in such a way that the cross sectional areas of the arms of the first star shaped holder widens when looking along the longitudinal axis from the first end toward the second end of the center portion, and wherein the arms of the second star shaped holder are oriented in such a way that the cross sectional areas of the arms of the second star shaped holder tapers when looking along the longitudinal axis from the first end toward the second end of the center portion. This provides a flow-optimized entrance of the gas mixture into as well as a flow-optimized exit of the gas mixture out of the adsorber structure. The wording when looking along the longitudinal axis from the first end toward the second end of the center portion is to be understood as in a direction along the longitudinal axis from the first end toward the second end of the center portion.

The above object is also achieved with a reactor for separating gaseous components such as carbon dioxide, methane or sulfur dioxide from a gas mixture in an adsorption mode comprising the features of claim <NUM>. Preferred embodiments are set out in dependent claims <NUM> to <NUM>.

According to the present invention the reactor comprises a housing having an inlet portion and an outlet portion and an adsorber structure as described above positioned in the housing between the inlet portion and the outlet portion. Optionally, the adsorber structure is positioned in a mid part of the housing. Preferably, the mid part of the housing together with the adsorber structure is adapted to be mounted in an ISO standardized and derivative intermodal shipping container such as a 20ft or 40ft container. Preferably, the mid part of the housing is positioned transversely to the longitudinal direction of the shipping container. The inlet portion and the outlet portion of the reactor are mounted to the outside of the container thereby being fluidically connected to the adsorber structure and the mid part of the housing inside the container. Preferably, the housing is adapted to receive the adsorber structure in a form fitting manner. The adsorber structure is fixed in position in the housing and is adapted to take loads acting on the housing. Thus, the wall thickness of the housing and its mass can be reduced. Preferably, the reactor is constructed modularly. Each part of the housing such as the mid part, the inlet portion and the outlet portion may be formed as modules which comprise the same connecting interfaces in the form of flanges and can thus easily be mounted together.

In an embodiment of the invention the housing comprises one or more shells, in particular two half shells which are adapted to circumferentially surround and abut the adsorber structure. Preferably, the housing has a cylindrical shape. A cylindrical shape is advantageous as it provides sufficient strength to the housing when a negative pressure is applied inside the housing. Preferably, the housing is adapted to withstand an absolute-negative pressure of up to <NUM> mbar without being damaged. Optionally, the mid part of the housing is formed by two half shells. Preferably, each of the half shells comprises flanges along the longitudinal axis of the center portion. The flanges facilitate mounting of the two half shells together. Optionally, the half shells and the adsorber structure are adapted to form a form fit when the two half shells enclose the adsorber structure. Forming the housing, in particular the mid part of the housing, by two half shells is advantageous as the adsorber structure is easily accessible for repair or maintenance. In order to access the adsorber structure only one half shell has to be removed from the second half shell which holds the adsorber structure.

In another embodiment of the invention the reactor further comprises a blower for drawing the gas mixture from the inlet portion through the adsorber structure towards the outlet portion. The inlet portion and the outlet portion each comprise a closure for closing the inlet portion and the outlet portion, respectively, in a desorption mode of the reactor, in which an absolute-negative pressure in the housing between the two closures is drawn and the sorbent elements of the adsorber structure are regenerated. Preferably, a vacuum pump is assigned to the reactor. The vacuum pump is configured to draw an absolute-negative pressure of up to up to <NUM> mbar in the housing between the two closures. The closures are preferably adapted to open and close the inlet and outlet portions in cycles. In particular, the closures are adapted to open the reactor during the adsorption mode of the reactor and to close the reactor during the desorption mode of the reactor.

In an embodiment of the invention the inlet portion and the outlet portion comprise a rectangular shape when looking along the longitudinal axis from the first end toward the second end of the center portion. In other words: the inlet portion and the outlet portion comprise a rectangular cross section in a plane extending transversely to the longitudinal axis of the center portion. Each closure is formed by multiple panels, preferably by two panels, which are rotatably mounted to the inlet portion and the outlet portion, respectively, such that the panels of each closure are rotatable between an open state and a closed state. In case the closure is formed by two panels both axes of rotation of the panels are preferably arranged transverse and at a distance to the longitudinal axis of the center portion. Both axes of rotation are parallel to each other. In the open state the panels are oriented parallel to the longitudinal axis of the central portion. In the closed state the panels are oriented transversely to the longitudinal axis of the central portion. The closures are adapted to allow the gas mixture to be drawn by the blower from the inlet portion through the adsorber structure towards the outlet portion in the open state and to prohibit the gas mixture to enter the inlet or the outlet portion in the closed state. Preferably, when being positions in the open state the closures are arranged parallel to the streaming direction of the gas mixture streaming from the first end to the second end of the center portion. Thus, the closures form a negligible flow resistance to the gas mixture. Each closure may comprise a support formed by a strut in the middle of the inlet portion and the outlet portion, respectively. Each closure may comprise an electromagnetic fastener mounted on the strut to pull the closures towards the adsorber structure and to facilitate drawing an absolute-negative pressure in the housing between the closures. A sealing may be provided on the strut in order to seal the strut against the panels during the desorption mode of the reactor. The rectangular shape of the inlet and outlet portion facilitates the manufacturing of the inlet and outlet potion and also simplifies the realization of the closures. Preferably, the inlet portion has a rectangular funnel shape.

In another embodiment of the invention the reactor further comprises a flushing element for flushing the adsorber structure, wherein the flushing element is positioned between the inlet portion and the adsorber structure. The flushing element is adapted to dispense a flushing gas, preferably containing steam, to wet and heat the sorbent elements. The sorbent elements are flushed during the desorption mode of the reactor. Desorption of the sorbent elements is achieved at a temperature of the sorbent elements of <NUM> to <NUM>, preferably of <NUM> to <NUM>, most preferably at <NUM>. The flushing element is housed in the housing of the reactor. The flushing element may form a further module comprising flanges to connect the flushing element e.g. to the inlet portion and the mid part of the housing, respectively.

In an embodiment of the invention the flushing element comprises an inner circular portion, an outer ring shaped portion, and conduits extending at a constant annular distance from the inner circular portion to the outer ring shaped portion in an radial outward direction, wherein each conduit is fluidically connected to a supply line via openings such as through holes in the outer ring shaped portion and comprises multiple openings such as holes or slits adapted to dispense flushing gas from the supply line into the reactor. Preferably, the flushing element and the first star shaped holder of the adsorber structure are concentrically arranged. Optionally, the flushing element is rotated relative to the first star shaped holder such that each of the conduits of the flushing element is positioned between two annular adjacent arms of the first star shaped holder when looking along the longitudinal axis from the first end towards the second end of the center portion. In other words: The flushing element is rotated relative to the first star shaped holder such that each of the conduits of the flushing element is positioned between two annular adjacent arms of the first star shaped holder when projecting the flushing element and the firs star shaped holders into one single plane which extends transversely to the longitudinal axis of the center portion. Thus, each conduit of the flushing element is positioned in a gap between adjacent sorbent elements, the gap extending from two circumferentially adjacent arms of the first star shaped holder and tapering towards the corresponding arm of the second star shaped holder. This position of the flushing element relative to the sorbent elements allows a uniform wetting of the sorbent elements and thus an optimized heating of the sorbent elements via the flushing gas.

In another embodiment of the invention the reactor further comprises an extraction element for extracting process gas from the reactor, wherein the extraction element is positioned between the adsorber structure and the outlet portion. The extraction element is adapted to extract process gas including the flushing gas together with the gaseous component such as CO<NUM> which has been released from the sorbent material. Preferably, the process gas is drawn through the extraction element by the same pump which draws the negative pressure in the reactor during the desorption mode of the reactor. The extraction element is housed in the housing of the reactor. The extraction part may form a further module comprising flanges to connect the extraction element e.g. to the outlet portion and the mid part of the housing, respectively.

In an embodiment of the invention the extraction element comprises an inner circular portion, an outer ring shaped portion, and conduits extending at a constant annular distance from the inner circular portion to the outer ring shaped portion in an radial outward direction, wherein each conduit is fluidically connected to an extraction line via openings such as through holes in the outer ring shaped portion and comprises multiple openings such as holes or slits adapted to extract process gas from the reactor into the extraction line. Preferably, the extraction element and the flushing element have the same geometry. Preferably, the extraction element and the second star shaped holder of the adsorber structure are concentrically arranged. Optionally, the extraction element is rotated relative to the second star shaped holder such that each of the conduits of the extraction element is positioned between two annular adjacent arms of the second star shaped holder when looking along the longitudinal axis from the second end towards the first end of the center portion. In other words: The extraction element is rotated relative to the second star shaped holder such that each of the conduits of the extraction element is positioned between two annular adjacent arms of the second star shaped holder when projecting the extraction element and the second star shaped holders into one single plane which extends transversely to the longitudinal axis of the center portion. This position of the extraction element relative to the sorbent elements allows an optimized flow control of the process gas.

The above object is also achieved with a use of the reactor of the present invention to capture a gaseous component such as carbon dioxide, methane or sulfur dioxide from atmospheric air. Preferably, the reactor is positioned in a 20ft or 40ft ISO standardized and derivative intermodal shipping containers transverse to the longitudinal direction of the container. This allows an easy and fast worldwide transport and installation of the reactor. Optionally, multiple reactors, such as six, eight, twelve or fourteen reactors, are arranged in one container. The reactors may be arranged on different levels in the container, such as e.g. on a lower level and on an upper level.

The invention will now be described in connection with an exemplary embodiment shown in the Figures in which:.

<FIG> and <FIG> show a DAC reactor <NUM> for separating gaseous components such as carbon dioxide, methane or sulfur dioxide from a gas mixture such as atmospheric air, in an adsorption mode. The DAC reactor <NUM> is in particular adapted for separating carbon dioxide from atmospheric air in an adsorption mode.

The reactor <NUM> comprises a housing <NUM> having an inlet portion <NUM>, an outlet portion <NUM> and a mid part <NUM> positioned between the inlet portion <NUM> and the outlet portion <NUM>. The reactor <NUM> further comprises an adsorber structure <NUM> positioned in the mid part <NUM> of the housing <NUM>.

The mid part <NUM> of the housing <NUM> has two half shells <NUM> which are adapted to circumferentially surround and abut the adsorber structure <NUM>. Each half shell <NUM> comprises flanges <NUM> extending in longitudinal direction of the reactor <NUM> and which allow a connection of the two half shells <NUM> via screws (not shown).

The reactor <NUM> further comprises a blower <NUM> for drawing the gas mixture from the inlet portion <NUM> through the adsorber structure <NUM> towards the outlet portion <NUM>.

The reactor <NUM> further comprises a flushing element <NUM> for flushing the adsorber structure <NUM> with a flushing gas during a desorption mode of the reactor <NUM>. The flushing element <NUM> is positioned between the inlet portion <NUM> and the adsorber structure <NUM>, in particular between the inlet portion <NUM> and the mid part <NUM> of the housing.

The reactor <NUM> also comprises an extraction element <NUM> for extracting process gas from the reactor <NUM> in the desorption mode. The process gas includes the flushing gas dispensed form the flushing element <NUM> and CO<NUM> released from the adsorber structure <NUM>.

Each part of the housing <NUM> such as the mid part <NUM>, the inlet portion <NUM> and the outlet portion <NUM> are formed as modules which comprise the same connecting interfaces in the form of flanges <NUM> and can thus easily be mounted together. Moreover, the blower <NUM>, the flushing element <NUM> and the extraction element <NUM> are also housed in the housing <NUM> and form further modules comprising flanges <NUM>. The flanges <NUM> are used to connect the blower <NUM>, the flushing element <NUM> and the extraction element <NUM> to the outlet portion <NUM>, to the inlet portion <NUM> as well as the mid part <NUM> and to the mid part <NUM> as well as the outlet portion <NUM> of the housing, respectively.

<FIG> shows the adsorber structure <NUM> in detail. The adsorber structure <NUM> is in particular adapted to capture gaseous carbon dioxide from a gas mixture, e.g. atmospheric air. The adsorber structure <NUM> comprises a cylindrical center portion <NUM> extending along a longitudinal axis <NUM> from a first end <NUM> to a second end <NUM>.

A first star shaped holder <NUM> is arranged at the first end <NUM>. A second star shaped holder <NUM> is arranged at the second end <NUM> of the center portion <NUM>. Each of the star shaped holders <NUM>, <NUM> comprises the same number of multiple arms <NUM> which extend at a constant angular distance from the center portion <NUM> in different radial outward directions. Each of the arms <NUM> of the first star shaped holder <NUM> and the second star shaped holder <NUM> comprise a cross sectional area oriented transversely to the radial outward extension of the arms <NUM>. The cross sectional area of each of the arms <NUM> has a triangular shape. The arms <NUM> of the first star shaped holder <NUM> are oriented in such a way that the cross sectional areas of the arms <NUM> of the first star shaped holder <NUM> widen when looking along the longitudinal axis <NUM> from the first end <NUM> toward the second end <NUM> of the center portion <NUM>. The arms <NUM> of the second star shaped holder <NUM> are oriented in such a way that the cross sectional areas of the arms <NUM> of the second star shaped holder <NUM> taper when looking along the longitudinal axis <NUM> from the first end <NUM> toward the second end <NUM> of the center portion <NUM>.

The star shaped holders <NUM>, <NUM> are rotated relative to one another such that each arm <NUM> of the first star shaped holder <NUM> is positioned between two adjacent arms <NUM> of the second star shaped holder <NUM> when looking along the longitudinal axis <NUM> from the first end <NUM> toward the second end <NUM> of the center portion <NUM>.

The adsorber structure <NUM> further comprises connecting members <NUM> extending from each arm <NUM> of the first star shaped holder <NUM> to the respective two adjacent arms <NUM> of the second star shaped holder <NUM>. Each of the connecting members <NUM>, the corresponding arm <NUM> of the first star shaped holder <NUM> and one of the respective two adjacent arms <NUM> of the second star shaped holder <NUM> form a frame <NUM>. Sealing elements (not shown) are arranged on the connecting elements <NUM> and are configured to seal the connecting elements <NUM> against an inner wall of the mid part <NUM> of the housing <NUM>.

The adsorber structure <NUM> further comprises sorbent elements <NUM> for adsorbing the gaseous components, in particular carbon dioxide, from the gas mixture. The sorbent elements <NUM> are supported by the frame <NUM>. Two sorbent elements <NUM> extend from each arm <NUM> of the first star shaped holder <NUM> to the respective two adjacent arms <NUM> of the second star shaped holder <NUM> along the longitudinal axis <NUM> of the center portion <NUM>. A gap <NUM> between adjacent sorbent elements <NUM> extending from two circumferentially adjacent arms <NUM> of the first star shaped holder <NUM> tapers towards the corresponding arm <NUM> of the second star shaped holder <NUM> such that a gas mixture streaming from the first end <NUM> to the second end <NUM> of the center portion <NUM> penetrates the adjacent sorbent elements <NUM>.

Each sorbent element <NUM> is formed by at least one sorbent module <NUM> comprising two parallel oriented grid structures <NUM> and sorbent material (not shown). The two grid structures <NUM> are arranged at a distance from one another thereby forming a receiving portion for the sorbent material. The sorbent material is arranged between the grid structures <NUM> in the receiving portion. Preferably, an amine-functionalized ion exchanger resin is used as a solid sorbent material.

<FIG> and <FIG> show the inlet portion <NUM> and the outlet portion <NUM> of the reactor <NUM> in detail.

The inlet portion <NUM> and the outlet portion <NUM> each comprise a closure <NUM> for closing the inlet portion <NUM> and the outlet portion <NUM>, respectively, in the desorption mode of the reactor <NUM>. In the desorption mode an absolute-negative pressure is drawn in the housing <NUM> between the two closures <NUM> and the sorbent elements <NUM> of the adsorber structure <NUM> are regenerated.

The inlet portion <NUM> and the outlet portion <NUM> comprise a rectangular shape when looking along the longitudinal axis <NUM> from the first end <NUM> toward the second end <NUM> of the center portion <NUM>. In particular, the inlet portion <NUM> comprises a rectangular funnel shape. Each closure <NUM> is formed by two panels <NUM> which are rotatably mounted to the inlet portion <NUM> and the outlet portion <NUM>, respectively, such that the panels <NUM> of each closure <NUM> are rotatable between an open state and a closed state. Each panel <NUM> is rotatable around an axis of rotation. Both axes of rotation are arranged transverse and at a distance to the longitudinal axis <NUM> of the center portion <NUM>. Both axes of rotation are parallel to each other. The panels <NUM> are oriented parallel to the longitudinal axis <NUM> (see <FIG>) of the center portion <NUM> in the open state of the closure <NUM>. In the closed state of the closure <NUM> the panels <NUM> are oriented transversely to the longitudinal axis <NUM> of the center portion12. Each closure comprises a support formed by a strut <NUM> in the middle of the inlet portion <NUM> and the outlet portion <NUM>, respectively. A sealing (not shown) is provided on the strut <NUM> in order to seal the strut <NUM> against the panels <NUM> during the desorption mode of the reactor.

As regards the inlet portion <NUM>, the strut <NUM> is mounted on an adapter piece <NUM> which connects the rectangular shape of the inlet portion <NUM> to the circular shape of the flushing element <NUM> (see <FIG>). The adapter piece <NUM> may comprise additional sealings (not shown) to seal the adapter piece <NUM> against the panels <NUM>.

As regards the outlet portion <NUM>, the strut <NUM> is mounted on the extraction element <NUM> (see <FIG>). The extraction element <NUM> may comprise additional sealings (not shown) to seal the extraction element <NUM> against the panels <NUM>.

Each closure <NUM> comprises an electromagnetic fastener (not shown) mounted on the strut <NUM> to pull the panels <NUM> of the closures <NUM> towards the adsorber structure <NUM> and to facilitate drawing of a negative pressure in the housing <NUM> between the closures <NUM>.

<FIG> and <FIG> show the flushing element <NUM> and the extraction element <NUM> in detail. The flushing element <NUM> and the extraction element comprise an inner circular portion <NUM>, an outer ring shaped portion <NUM>, and conduits <NUM> extending at a constant annular distance from the inner circular portion <NUM> to the outer ring shaped portion <NUM> in a radial outward direction. Each conduit <NUM> of the flushing element <NUM> is fluidically connected to a supply line (not shown) via openings <NUM> formed as through holes in the outer ring shaped portion <NUM> and comprises multiple openings <NUM> such as holes or slits adapted to dispense flushing gas from the supply line into the reactor <NUM>. The conduits <NUM> of the extraction element <NUM> are fluidically connected to an extraction line (not shown) via openings <NUM> formed as through holes in the outer ring shaped portion <NUM> and comprise multiple openings <NUM> such as holes or slits adapted to extract process gas from the reactor <NUM> into the extraction line.

<FIG> shows the reactor <NUM> together with peripheral components. In the following the use of the reactor <NUM> to capture CO<NUM> from atmospheric air will be explained with reference to <FIG>.

In the adsorption mode the blower <NUM> draws the gas mixture in the form of ambient air from the inlet portion <NUM>, as indicated by arrow <NUM>, through the adsorber structure <NUM> towards the outlet portion <NUM>. The sorbent elements <NUM> capture CO<NUM> out of the ambient air and CO<NUM> depleted air leaves the reactor <NUM> as indicated by arrow <NUM>. This step is completed when the sorbent elements <NUM> are fully saturated with CO<NUM>.

In order to regenerate the sorbent elements <NUM> the reactor <NUM> is switched into the desorption mode. The blower <NUM> is turned off and the closures <NUM> of the inlet portion <NUM> and the outlet portion <NUM>, respectively, are closed. A vacuum pump <NUM> which is connected to the reactor <NUM> via an extraction line <NUM> draws an absolute-negative pressure of up to <NUM> mbar in the reactor <NUM>.

Flushing gas is provided to a supply line <NUM> as indicated by arrow <NUM>. The supply line <NUM> is connected to the flushing element <NUM> at the inlet portion <NUM> of the reactor <NUM>. The flushing gas is subsequently heated and is supplied via the supply line <NUM> to the flushing element <NUM>. The flushing element <NUM> dispenses the flushing gas into the reactor <NUM> at the inlet portion <NUM> thereby uniformly wetting and heating the sorbent elements <NUM>. The sorbent elements <NUM> are heated to a temperature of <NUM> to <NUM>°, preferably of <NUM> to <NUM>, most preferably of <NUM>. This temperature range/temperature causes a desorption of CO<NUM> from the sorbent elements <NUM>. The vacuum pump <NUM> draws a process gas comprising the flushing gas and the released CO<NUM> out of the reactor <NUM> into the extraction line <NUM> via the extraction element <NUM> at the outlet portion <NUM> of the reactor <NUM>. CO<NUM> and flushing gas are separated and leave the extraction line <NUM> through different outlets (arrow <NUM> for flushing gas and arrow <NUM> for CO<NUM>).

Claim 1:
An adsorber structure for capturing gaseous components from a gas mixture, the adsorber structure (<NUM>) comprising a cylindrical center portion (<NUM>) extending along a longitudinal axis (<NUM>) from a first end (<NUM>) to a second end (<NUM>),
a first star shaped holder (<NUM>) arranged at the first end (<NUM>), and
a second star shaped holder (<NUM>) arranged at the second end (<NUM>) of the center portion (<NUM>),
wherein each of the star shaped holders (<NUM>, <NUM>) comprises the same number of multiple arms (<NUM>) which extend at a constant angular distance from the center portion (<NUM>) in different radial outward directions,
wherein the star shaped holders (<NUM>, <NUM>) are rotated relative to one another such that each arm (<NUM>) of the first star shaped holder (<NUM>) is positioned between two adjacent arms (<NUM>) of the second star shaped holder (<NUM>) when looking along the longitudinal axis (<NUM>) from the first end (<NUM>) toward the second end (<NUM>) of the center portion (<NUM>), wherein the adsorber structure (<NUM>) further comprises sorbent elements (<NUM>) for adsorbing the gaseous components from the gas mixture,
wherein two sorbent elements (<NUM>) extend from each arm (<NUM>) of the first star shaped holder (<NUM>) to the respective two adjacent arms (<NUM>) of the second star shaped holder (<NUM>) along the longitudinal axis (<NUM>) of the center portion (<NUM>) and,
wherein a gap (<NUM>) between adjacent sorbent elements (<NUM>) extending from two circumferentially adjacent arms (<NUM>) of the first star shaped holder (<NUM>) tapers towards the corresponding arm (<NUM>) of the second star shaped holder (<NUM>) such that a gas mixture streaming from the first end (<NUM>) to the second end (<NUM>) of the center portion (<NUM>) penetrates the adjacent sorbent elements (<NUM>).