The present disclosure relates to the field of reaction chambers and in particular to thermal reaction chambers for gaseous thermal reactions.
Thermal reactors, such as plasma reactors, are used to react gases into forming different compounds in various fields, such as fuel conversion and removal of pollutants from gas streams. A discharge or excitation by electromagnetic waves, such as radiofrequency or microwaves, of high intensity is applied to a fluid containing the substances to be treated causing decomposition, and possibly recombination, of substances.
There are different demands on the thermal reactor depending on the type of thermal reactions or plasma that can vary in both temperature and intensity. Consequently, different reactor chamber designs for these reactions exist today, such as tubular reactors allowing the fluid to pass through the plasma arranged in the middle of the tube.
One plasma reactor is presented in US2003/0024806 A1 wherein a plasma is combined with comminution means to provide for enhanced angular momentum within the chemical reactor.
High temperature thermal reactions such as plasmas are energy demanding and in order to ensure satisfactory reaction yield in combination with energy efficiency there are improvements to be made over prior art.
The present disclosure aims to provide a thermal reactor with satisfactory reaction yield in combination with energy efficiency. The inventors have realized that such a reactor should overcome the majority, preferably all, of the following problems:
Accordingly, the present disclosure provides the following listing of itemized embodiments:
Aspects and embodiments are now described, by way of example, with reference to the accompanying drawings, in which:
As a first aspect of the present disclosure there is provided a thermal reactor comprising:
The first as well as second circumferential surfaces are imaginary and are arranged along the outside of the cage. They can be imaginary arranged around the cage in any way except of being parallel and overlapping only the same holes, i.e. the holes are mutually different. For example, a cylindrical cage having one line of slits as holes does not form part of the subject matter of the first aspect of the present disclosure since, even though there can be arranged two imaginary non-parallel circumferential surfaces, the holes, i.e. slits, will not be mutually distinct since the first and second circumferential surface will include the same set of holes. It is advantageous to have more than one set of holes being mutually distinct, i.e. more than only one row of holes, since the flow on the inside of the cage is more homogenous. A more homogenous flow is better for the reaction in the thermal reaction zone as the reactants enter more evenly.
That the first subset of holes and the second subset of holes are mutually distinct means that they are not the same holes.
The holes of the cage are openings. The holes in the cage can have different geometries and can for example be circular, oval, rectangular, quadratic, slits or polygons. The holes can also have irregular shapes or have a mixture of regular shapes, such as some holes circular and some holes oval. The holes can also be a mixture of regular and irregular shapes. The holes can also be referred to as apertures. The holes can vary in size over the cage or they can be uniform. Preferably, the holes are circular. The diameter of the holes is typically less than 5 cm, such as less than 2 cm, such as less than 5 mm. The area of the holes is typically less than 20 cm2, such as less than 10 cm2, such as less than 20 mm2.
The hole-ratio distribution (i.e. number of holes x hole surface/total surface) over the cage surface can be uniform or it can vary to create specific desired flow patterns inside the cage. Certain parts of the cage can also have fewer holes or even be closed/without holes. One example of such a case is that the part of the cage closest to the outlet of the vessel is closed so that by-passing of unreacted cold gas is reduced or avoided.
The gas inlet of the vessel is in fluid connection to the cage. The vessel and the cage are provided with a mutual gas outlet. By mutual gas outlet is typically meant that the cage is arranged on a part of a wall of the vessel, wherein on said wall is a mutual outlet of both the cage and the vessel. Alternatively, the cage is separated from the wall and the outlet of the cage and the outlet of the vessel share a mutual outlet by means of a pipe. The gas inlet typically is a part of the wall of the vessel, since the inlet and the cage are in fluid connection, gas can enter into the vessel and be directed to the cage. The gas is typically directed by an overpressure of the gas pushing it towards the cage.
The gas permeable cage provides for that there is at least a first pressure, P1, outside the cage and at least a second pressure, P2, inside the cage and that P1 is higher than P2. Thereby, a pressure gradient is present between the outside and the inside of the cage. As a consequence, the design of the gas passage through the cage allows to control the gas velocity at each point, both inside and outside of the cage. This makes it possible to achieve a flow that does not reverse at any point within the cage but instead all gas molecules are uninterruptedly approaching towards and into the thermal reaction zone and turbulences can be kept controlled. Consequently, the movement of the gas towards and into the thermal reaction zone without reversing away from the thermal reaction zone is secured.
Moreover,
The thermal reaction zone is arranged inside the cage which acts as a reaction chamber. When in use, gas enters through the cage holes and continues further on into the thermal reaction zone. Upon entry of the gas through the holes of the cage surrounding the thermal reaction zone a pressure gradient is formed. The pressure gradient is defined as the difference between two pressures in corresponding points/volumes. By corresponding is meant that both points/volumes are situated at the same distance, d, from the cage wall on an imaginary straight line that is drawn from inside of the cage to outside of the cage, wherein the line is perpendicular to the surface of the cage wall. At the point/volume outside of the cage the at least first pressure P1 is determined and at the point/volume inside of the cage the at least second pressure P2 is determined. At every point on the cage wall along a similar imaginary perpendicular line, the pressure just outside of the cage is higher than the pressure just inside the cage at an infinitesimal distance from the cage wall. This pressure gradient gives rise to the transport of the gas through the cage wall.
The pressure gradient controls the velocity of the gas towards the thermal reaction zone, causing the gas to become less turbulent and more uniform in speed, which in turn secures the movement of the gas into the thermal reaction zone without reversing as well as improving the residence time distribution of the gas in the thermal reaction zone. Thereby dilution of the thermal reaction zone with fast by-passing unreacted cold gas is typically reduced or avoided. Influence on the thermal reaction zone of turbulence occurring in the immediate vicinity of the holes of the cage can be avoided by applying a sufficient size of the cage for the turbulence to disappear or sufficiently damp off before reaching the thermal reaction zone. In addition to the pressure gradient, when the gas enters through the holes of the cage, the cooler incoming gas will protect the walls of the vessel as well as the cage from the hot thermal reaction zone. The cage will also protect the vessel from part of the irradiation, both heat and electromagnetic, from the thermal reaction zone, by completely or partially reflecting the radiation back into the thermal reaction zone.
The cage can be of different shapes wherein non-limiting examples of the shape includes spherical, half-spherical, ellipsoid, cylindrical, rectangular, quadratic, cone, pyramid or polygonal prisms. Typically, the cage a central longitudinal axis around which the cage is symmetrical.
The corners of the cage may be angled or rounded or may have another three-dimensional form. Preferably, the corners are rounded and there are no sharp corners or edges. A preferred shape is an ellipsoid. Another preferred shape is a combination of ellipsoids and cylinders or cones into rounded forms where the joints between the different geometries are smooth without any edges or corners. Preferably, the three-dimensional derivative of the surface of the cage can be described by a continuous function, thereby the surface is smooth without any sharp edges. Such geometry is beneficial as there are no edges wherein gas would be delayed or allowed to create turbulences with the consequences that that the residence time distribution would be impaired and making it more difficult to control a gas flow in a controlled way. Preferably, also the second derivative of the continuous function is a continuous function meaning that the gas flow will not be interfered by differences in flow pattern from cage-walls with different geometries.
The cage may comprise an opening being larger than a hole on at least one side. Such opening is in such case typically arranged so that reaction products exiting the thermal reaction zone can be transported to the outlet of the vessel through the opening.
Preferably, at least 80% of the holes, such as at least 90% of the holes, have a central axis (Y) that is angled at an angle α being between 80°-100° relative to a tangential plane (X) at an outer surface of the cage around respective hole. By having such angle, the holes are substantially straight compared with the outer surface at each hole. Substantially straight holes minimize the rotation of the gas on the inside of the cage by causing as little as possible of an angular momentum. This is beneficial as to have as little by-pass of gas as possible, i.e. avoiding that the gas is transported along the inner walls of the cage instead of into the thermal reaction zone.
Typically, at least 30%, such as at least 40%, such as at least 50%, such as at least 60%, such as at least 70%, such as at least 80%, such as at least 90%, of the surface of the cage is provided with holes. That the surface is provided with holes means that there are holes distributed over that section of the surface. The entire surface, i.e. 100%, of the cage may be provided with holes. If the surface is covered to 100% by holes this means that there are no sections of the surface of the cage that does not have holes. Preferably, the distance between the holes is less than 10 cm, such as less than 5 cm, such as less than 3 cm, such as less than 5 mm. The cage is typically provided with at least 20 holes. It is beneficial to have a tight distance between the holes so that the flow on the inside of the cage is more homogenous with only minor rotations after passing the holes into the cage. The velocity of the flow is decreased by an even distribution of holes and a decreased velocity means that Reynold's number is decreased, which is beneficial as it minimizes turbulence.
The thermal reactor is typically a plasma reactor, the thermal reaction zone is typically a plasma zone and the temperature generating means are typically plasma generating means.
Typically, the vessel is a pressurized vessel. Pressurized refers to a pressure deviating from atmospheric pressure, the pressure is preferably above atmospheric pressure.
Typically, the cage is spaced from the walls of the vessel. As a consequence, the walls of the vessel are protected from the heat of the thermal reaction zone both by the gas barrier present between the walls of the vessel and the cage as well as by the gas barrier present between the cage and the thermal reaction zone. The cage can be spaced from all walls or parts of the walls, such as from all walls except the wall comprising the outlet of the vessel.
The temperature generating means are arranged to create a thermal reaction zone within the vessel and are typically arranged to create a localized thermal reaction zone, for example by focusing irradiation or discharge energy to a specific point or area or volume.
In one embodiment, the temperature generating means are electrodes. The electrodes can produce a thermal reaction zone, such as a plasma, through electric discharges. The electrodes are typically positioned inside or in direct vicinity of the thermal reaction zone.
In another embodiment, the temperature generating means are antennas. Typically, the antennas are plasma antennas adapted for radiofrequency waves or microwaves. A plasma generated from electromagnetic waves of radio frequency or microwaves can be localized for example by focusing irradiation to a specific point or area or volume and can therefore be arbitrarily or preferably optimally positioned inside the cage. Typically, the antennas are positioned in the walls of the vessel. The antennas may also be positioned in the walls of the cage.
The vessel may further comprise cooling means. The cooling means may be adapted for liquid quenching, such as nozzles for spraying liquid, e.g. water. Alternatively, the cooling means may be adapted for gas quenching. The cooling means are typically arranged so that the flow of quenching liquid or quenching gas is directed towards the outlet of the vessel or further downstream. Preferably, the cooling means are arranged in the outlet or in direct connection to the outlet.
The cage may be made of a porous material. In such a case, the gas is forced through the pores to enter the thermal reaction zone. A porous cage having long pores having a high length to width ratio that even further reduces the turbulence of the gas causing the flow to become laminar or essentially laminar already upon entry into the cage.
The cage may be a mesh. A mesh is a continuous structure built up in such a way that it is provided with openings. An example of a mesh is expanded metal sheets, wherein multiple slits in a sheet are made followed by stretching the sheet. The stretching creates a diamond opening pattern. Another example of a mesh is a perforated metal sheet that is made from sheet steel that has been fed through a machine that punches out holes that can be straight rows or staggered to increase the amount of the openings. A further example of a mesh is welded wire mesh comprising grids of parallel longitudinal wires being welded to cross wires at the required spacing. Yet another example of a mesh is a woven wire mesh that is made as a cloth with wire threads woven lengthwise and perpendicular at certain angles.
The cage may be made of a material that is transparent or almost transparent to radio—and microwave-frequency electromagnetic waves and thus does not interact with radio frequency (RF) waves or microwaves, to avoid reflections and absorption, in order to suit operation with longer wavelengths. Typically, in such a case, the cage is a ceramic cage made from a ceramic material, such as alumina (Al2O3) or alumina-based ceramics, corundum or fused quartz or borosilicate glasses, SiO2, boron nitride, silicon nitride or other silica ceramics or ZrO2 or other zirconia ceramics. The thermal generating means can in such a case be positioned outside of the cage, preferably in or on one or more of the wall(s) of the vessel.
Alternatively, the cage is a metal cage. The cage can be made of metal or be coated with metal or contain parts of metal, such as threads of metal. The metal cage or metal-coated cage may reflect heat irradiation back towards the thermal reaction zone. A metal cage typically creates a Faraday cage that causes the electromagnetic waves to reflect inside the cage and that enhances reflection of heat irradiation coming from the thermal reaction zone. Preferably, the openings of the Faraday cage have small dimensions to avoid or minimize electromagnetic leakage. The cage is preferably made of a conductive metal or metal alloy. The temperature generating means, typically plasma generating means, are arranged to create a thermal reaction zone, typically a plasma zone, within the cage. The temperature generating means are typically positioned in at least one wall of the cage or inside the metal cage, preferably on a cage side wall.
Alternatively, the cage is made of a non-metallic conductive material, preferably from graphene or reduce graphene oxide or graphene-metal composites.
In one embodiment, the thermal reactor the gas permeable cage is a first gas permeable cage and the thermal reactor further comprises:
a second gas permeable cage, wherein the holes of the first gas permeable cage are first holes, and the second gas permeable cage is provided second holes, wherein the second gas permeable cage is smaller than the second gas permeable cage, so that the second gas permeable cage is arranged inside the first gas permeable cage.
Preferably, the first and second holes of the first and second gas permeable cages are arranged offset so that the first and second holes are not aligned. In such embodiment, the holes of cages arranged in direct vicinity of each other are offset so that the incoming gas is forced in a non-straight motion entering the cage. It is beneficial that the holes are not aligned since this is causing the turbulent energy of the gas outside the cage to decrease more efficiently. Typically, the first gas permeable cage and the second gas permeable cage have the same geometrical shape. By same geometrical shape is meant that both gas permeable cages are ellipsoids, cylinders, cones or any other suitable shape for the cage.
It is beneficial to arrange a first gas permeable cage inside a second gas permeable cage since diffusivity is decreased and, consequently, also the turbulence of the gas entering into through the first and second gas permeable cage. In embodiments, there are at least three, such as at least four, such as at least five gas permeable cages arranged inside one another so that upon entry of the gas, the gas is forced in a in a zig-zag motion into the inside of the cages. A zig-zag motion effectively decreases turbulence of incoming gas.
The thermal reactor is suitable for use in gaseous reactions including but not limited to fuel conversion, removal of pollutants from gas streams, production of hydrogen gas and nitrogen-containing compounds.
As a second aspect of the present disclosure, there is provided a thermal reactor comprising a vessel, said vessel comprising a gas inlet, an outlet, a gas permeable cage, and temperature generating means arranged to create a thermal reaction zone within the cage, wherein the cage is provided with holes, wherein there is at least a first pressure, P1, outside the cage and at least a second pressure, P2, inside the cage, wherein P1 is higher than P2 so that a pressure drop is obtained over the cage wall.
The examples and embodiments discussed above in connection to the first aspect apply to the second aspect mutatis mutandis.
The present disclosure will now be described hereinafter with reference to the accompanying drawings, in which certain embodiments of the invention are shown.
These aspects may, however, be embodied in many different forms and should not be construed as limiting; rather, these embodiments are provided by way of example so that this disclosure will be thorough and complete, and to fully convey the scope of all aspects of invention to those skilled in the art. Like numbers refer to like elements throughout the description.
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Number | Date | Country | Kind |
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2051365-1 | Nov 2020 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SE2021/051160 | 11/22/2021 | WO |