Patent Application
20250186961
The present invention relates to a sealing system for a tubular reactor, a particular a catalytic reactor and a method of loading said sealing system inside a tubular reactor.
The sealing system inserted in the tubular reactor prevents gas leakage between the inside and the outside of said tubular reactor.
The sealing system, which is the subject of the invention, relates to all uses for which sealing of a tubular reactor is sought in a wide temperature range which extends from cryogenic temperatures, passing through ambient, up to high temperature levels, which can reach and even exceed 1000° C.
One possible field of use of the invention is the catalytic steam reforming of hydrocarbons for the production of a hydrogen-rich gas. As process gas a mixture of steam, hydrocarbon and/or carbon dioxide is used. This gaseous mixture is fed at temperatures of about 400 DEG-600 DEG C. and pressures up to 4 MPa to a reaction chamber which may consist of a plurality of catalyst-filled tubes and is heated there to about 750 DEG to 800 DEG C. This gaseous mixture then reacts endothermically via the catalyst to form a hydrogen-rich gas containing portions of carbon monoxide, carbon dioxide and excess steam and hydrocarbon.
An example of catalyst tube is described in the document WO 2018/077969. This document describes a catalyst tube in a fired heater, which consists of an outer reactor tube 1, catalyst 2, an inner tube 5, a boundary between catalyst tube and inner tube 3 and inlet barrier 4, an outlet barrier 6 and an outlet reducer 7. This is shown in
Tubular reactors traditionally do not include the internal heat exchanger tubes as described in the above example (i.e. regenerative reactor). Revamping those conventional tubes that have been in use for some time with such regenerative reactor concept to improve the plant efficiency. In many cases this catalyst tube contains catalyst support grid at the bottom of the tube, which is a grid plate with holes in it. As a result, a simple conical sealing will not work. In case the grid plate can be removed, the conical surface of the outlet reducer in an existing tube is also not necessarily machined to achieve a perfectly matching conical surface with the seal and thus leakage of gas is likely.
Note these tubular reactors that have been in use for some time may also be subject to the following problems: weld shrinkage, weld protrusion as well as fabrication tolerances already present in new tubes as well as possible creep growth of the diameter of the tubular vessel. Therefore, the sealing device during installation shall be able to pass the minimum diameter taking into account these problems while it should still seal at the maximum diameter after creep growth.
The present invention aims to overcome these drawbacks and provide a new sealing system for tubular reactors.
A solution of the present invention is a sealing system for a tubular reactor 10 comprising an inner wall 11, comprising a main body 60 having a circular section 61 and comprising a peripheral wall 62 configured so that at least its upper part matches the inner wall of the tubular reactor, said peripheral wall 62 comprising at least an annular lodging 22 comprising a sealing ring 50 sitting on an annular pusher 40, with the pusher configured to push the sealing ring in the peripheral wall 62 of the main body 60 and the main body 60 having a sufficient weight to push the sealing ring 50 against the inner wall 11 of the tubular reactor 10.
The sealing system can be understood as a sealing system for a tubular reactor comprising an inner wall, comprising a main body and comprising a peripheral wall having a circular section located at an upper part of the peripheral wall, the circular section having a diameter smaller than a diameter of the inner wall of the tubular reactor, said peripheral wall having a tapered section, providing an annular lodging extending between the inner wall of the tubular reactor and the tapering section, the annular lodging comprising a sealing ring sitting on an annular pusher, the sealing ring configured to, with the pusher, push an inner face of the sealing ring against the peripheral wall of the main body and the main body having a sufficient weight to push an outer face of the sealing ring against the inner wall of the tubular reactor.
In the sealing system according to the present invention, the sealing is made by the compression of the sealing ring between the annular pusher 40, the peripheral wall of the main body and the inner wall of the tubular reactor 10.
In the present invention, the expression “its upper part matches the inner wall of the tubular reactor” means that the space between the inner wall of the tubular reactor and the upper part of the peripheral wall of the main body is of between 0.5 and 5 mm, e.g. between 1 and 3 mm. In fact, the space can be maximum slightly smaller (0.5 mm) than the minimum width of the sealing ring. And minimum space is a diameter of the peripheral wall of the main body 0.5 mm smaller than the minimum reactor wall to allow installation of the sealing system. Inventors found that the spacing advantageously provides maneuvering during installation, e.g. to pass obstacles such as protrusion inside the tubular reactor or weld shrinkages.
Advantageously, the sealing system can have a height of between 25 and 500 mm, preferably between 25 and 100 mm. The circular section of the main body can have a diameter of between 25 mm and 500 mm, preferably 100 and 150 mm Note, the diameter of the circular section of the main body is slightly less than the inner diameter of the tubular reaction. For this reason, at least upper part of the peripheral wall of the main body matches the inner wall of the tubular reactor. Note that the height of the sealing system can be adjusted to seal at the most optimal location of the peripheral wall.
According to the present invention, the “sufficient weight of the main body” is a weight of between 10 and 10 000 kg, preferably between 100 and 500 kg. The “sufficient weight” includes both static weight from the sealing system as well as the dynamic weight resulting from the differential pressure over the sealing system. Note that the higher the weight on the sealing system, the tighter the sealing will be.
The sealing ring may be formed in any suitable manner. However, it will generally be sufficiently compressible to accommodate the smallest diameter of the tubular reactor. The sealing ring will generally be a flexible seal. A compressible split ring or a ring having a high coefficient of expansion could be used. The sealing ring may be formed of any suitable material provided that it can withstand the reaction conditions. Typically, the sealing ring material can be selected from carbon steel, aluminum, stainless steel, high nickel alloys, other alloys, ceramics or any material able to withstand the deformation and reaction conditions.
The other elements of the sealing system may be formed of any suitable material. Such material will generally be selected to withstand the operating conditions of the reactor. Generally, these elements will be fabricated from carbon steel, aluminum, stainless steel, high nickel alloys, other alloys or any material able to withstand the deformation and reaction conditions.
Depending on the embodiment, the sealing system according to the present invention can comprise one or more of the following features:
An example of a sealing system according to the invention is shown
An example of a sealing system according to the invention, wherein the main body comprises a channel 63 opening on both sides and configured to be connected to a tube 90 inside the tubular reactor, is shown
According to one variant, the base 20, the pusher 40 and the connecting means 30 are made of one piece, or multiple pieces connected together.
Advantageously, the annular lodging 22 comprises multiple concentrical sealing rings 50 and the pusher 40 is configured to push the concentrical sealing rings simultaneously. According to one variant, the annular lodging 22 comprises N concentrical sealing rings sitting on N concentrical annular separate pushers, with N comprised between 2 and 4. Note the concentrical sealing rings are contacted each another. Each sealing ring have a wall matching a wall of the sealing ring with which it is in contact. The inner most ring 55 comprises a smooth inner wall configured for matching the top wall of the lodging (cf.
Another object of the present invention is a tubular reactor comprising a sealing system as defined in the present invention and means for keeping said sealing system in the tubular reactor, e.g. at at least one end of the tubular reactor, preferably in the bottom part of the tubular reactor.
Preferably, the tubular reactor according to the present invention is a vertical reactor with downflow. Reactant(s) flow downwardly through the tubular reactor and thus first contact the upper surface of the sealing system, more specifically the surface of the main body of the sealing system.
Advantageously, the tubular reactor can have a height of between 1 and 30 m, preferably between 10 and 14 m.
Advantageously, the tubular reactor can have a circular section having a diameter of between 25 and 500 mm, preferably between 100 and 150 mm.
Advantageously, the sealing system can be installed up to 1000 mm, preferably to 150 mm away from the outlet of the tubular reactor.
Advantageously, the tubular reactor according to the present invention is a tubular reactor for catalytic conversion of a process gas, in other words the tubular reactor is a catalyst tube.
According to a more preferential variant, said tubular reactor is a reactor for catalytic conversion of process gas and comprises:
The catalyst in the outer annulus can be supported on the main body 60 of the sealing system or a bottom catalyst support 81.
In other words, the sealing system according to the invention can be added to the catalyst tubular reactor as described in the document WO 2018/077969. Preferably, the catalyst is used to conduct catalyst conversion reaction, preferably to revamp a reformer.
As explained above an example of catalyst tube according to the present invention is shown
Finally, another object of the present invention is a method of loading a sealing system according to the present invention inside a tubular reactor comprising a compression step of the sealing ring before loading and a decompression step of the sealing system after loading.
Advantageously, the sealing ring comprises a part divided longitudinally into two sub-parts, an upper sub-part and a lower sub-part, configured to be superimposed one on the other or only overlap according to the compression exerted on the sealing ring and the compression step implements one of the following compressions means:
These different compressions means are represented
Note the insertion of the pin half way in lower sub-part of the sealing ring avoids leakage when the pin is dissolved at high temperature.
In compressed state the sealing is minimal and to ensure optimum sealing, the mean of compression shall be removed/disconnected before reaching operating conditions.
In all these cases, means can be decomposing at temperature lower than normal operating temperature, but is strong enough at room temperature to maintain the ring in compressed state during loading. Typically, the decomposing temperature is between 100 and 500 and operating temperature is between 60° and 800° C. Alternatively, these materials can be dissolving in the operating fluid. Another alternative is that the material collapses/breaks under the weight and or pressure difference along the seal, allowing the ring to expand freely.
Typically, the tape or band material can be selected from plastic, paper, ceramics or metal
Typically, the pin material can be selected from plastic or metal
Typically, the glue material can be selected from epoxy glues, isocyanate glues or other single or multiple components glues.
Typically, the material for soldering can be selected from brazing material with a melting point at least 100° C. below operating temperature.
Alternatively, a temporary thin band or tube can be installed around the compressed sealing ring this is removed after installation.
In case the sealing system would have to be removed after a certain time in operation, the main body can be pulled (either by a tube or a lug connected to the main body) to release the force on the sealing ring. Subsequently the sealing ring will be released, and the complete sealing system can be removed from the tube.
The different objects of the present invention have several advantages.
Firstly, a major advantage of the invention is that the sealing system can handle changes in diameter of the tubular reactor. In general, when ring type seals are applied the tolerances on the tube inside diameter and the ring dimensions required very tight tolerances (<0.1 mm). The sealing design in the invention can handle significantly larger tolerances (typically up to several mm) as the weight and/or pressure drop of the main body enables the pusher to push the sealing rings upwards. The inclined wall of the lodging of the peripheral wall of the main body where the sealing ring slides on will expand the diameter of the ring and thereby ensuring that there is a tight seal between the inner wall of the tubular reactor and the main body in all scenarios. This benefit is especially beneficial in case of applications in tubular reactors that have been used in operation as the tolerances might not have been optimized for the sealing. Additionally in high temperature application creep of the materials is a known phenomenon. As a result of creep, the diameter of a tubular reactor can increase slightly over time. The weight energized sealing design ensures that the sealing ring is always in a tight fit between the tubular reactor and the main body throughout the tube lifetime. The sealing will this not reduce during the lifetime of the tubular reactor.
Secondly, because the sealing ring is pushed tightly against the inner wall of the tubular reactor by the main body and by the weight of the sealing system, the required pretension in the sealing ring is of less importance. This is especially important for high temperature applications where the material strength reduces. The present invention therefore decreases the leakage past the sealing system. The sealing ring is designed such that the reactor tubular diameter between nominal size minus up to 4 mm and nominal size plus up to 4 mm deviation is covered.
Thirdly, the present invention allows for applying a seal in applications where the sealing is placed on top of some existing structure, which does not have to be straight. The base can be adjusted to the surface where it is supported on. The actual sealing between the tube and the housing is than achieve a slightly higher elevation where there is no obstruction. This can be especially useful in case of welds applied in the bottom of the tubular reactor.
The solution of the present invention is especially beneficial in case of installation on the bottom of a tube as the gravity will ensure sufficient load on the sealing device to ensure the tightness of the sealing ring 50. However, the sealing can also be applied in horizontal position, at the top of the tube or at an inclination. In those cases, it might be required to apply an additional static load on the sealing.
The present invention further provides a sealing system for a tubular reactor according to the following clauses 1 to 10; a tubular reactor comprising the sealing system as defined in any one of clauses 1 to 10; a use of the tubular reactor according to clause 12; and a method of loading the sealing system as defined in any one of clauses 1 to 10 inside a tubular reactor:
Clause 1. Sealing system for a tubular reactor (10) comprising an inner wall (11), comprising a main body (60) having a circular section (61) and comprising a peripheral wall (62) configured so that at least its upper part matches the inner wall (11) of the tubular reactor, said peripheral wall (62) comprising at least an annular lodging (22) comprising a sealing ring (50) sitting on an annular pusher (40), with the pusher (40) configured to push the sealing ring (50) in the peripheral wall (62) of the main body and the main body (60) having a sufficient weight to push the sealing ring (50) against the inner wall (11) of the tubular reactor (10).
Clause 2. Sealing system according to clause 1, comprises a base (20) configured to support at least the pusher (40) by connecting means (30).
Clause 3. Sealing system according to clause 2, wherein the connecting means (30) are chosen from among a cylinder or connecting rods.
Clause 4. Sealing system according to clause 2 or clause 3, wherein the height of connecting means (30) is such that it enables the axial movement of the main body (60) above the base (20).
Clause 5. Sealing system according to any one of clauses 1 to 4, wherein the lodging (22) comprises at least one smooth and straight top wall projected towards the inner wall (11) of the tubular reactor (10).
Clause 6. Sealing system according to any one of clauses 1 to 5, wherein the inner wall of the pusher (40) is noticeably parallel to the top wall of the lodging (22).
Clause 7. Sealing system according to any one of clauses 1 to 6, wherein the sealing ring (50) comprises a smooth inner wall configured for matching the top wall of the lodging (22).
Clause 8. Sealing system according to any one of clauses 1 to 7, wherein the peripheral wall (62) of the main body (60) comprises steps configured to lift at least the connecting means (30), the pusher (40) and the sealing ring (50) during loading and/or unloading the sealing system in the tubular reactor.
Clause 9. Sealing system according to any one of clauses 1 to 8, wherein the sealing ring (50) comprises a part divided longitudinally into two sub-parts configured to be superimposed one on the other or only overlap according to the compression exerted on the sealing ring.
Clause 10. Sealing system according to any one of clauses 1 to 9, wherein the main body (60) comprises a channel opening on both sides and configured to be connected to a tube (90) inside the reactor or a tube outside the reactor.
Clause 11. Tubular reactor comprising a sealing system as defined in any one of clauses 1 to 10 and means for keeping said sealing system at least one end of the tubular reactor.
Clause 12. Tubular reactor according to clause 11, wherein said tubular reactor is a reactor for catalytic conversion of process gas and comprises:
Clause 13. Use of a tubular reactor according to clause 11 or 12 to conduct catalyst conversion reaction, preferably to revamp a reformer.
Clause 14. Method of loading a sealing system as defined in any one of clauses 1 to 10 inside a tubular reactor comprising a compression step of the sealing ring before loading and a decompression step of the sealing system after loading.
Clause 15. Method of loading according to clause 14, wherein the sealing ring comprises a part divided longitudinally into two sub-parts, an upper sub-part and a lower sub-part, configured to be superimposed one on the other or only overlap according to the compression exerted on the sealing ring and the compression step implements one of the following compressions means:
Clause 16. Sealing system according to any one of clauses 1 to 10, wherein the sealing ring (50) comprises of two or more concentric rings and the pusher 40 is configured to push the concentrical sealing rings simultaneously. The concentrical sealing rings are contacting each another. Each sealing ring having a wall matching a wall of the sealing ring with which it is in contact. The inner most ring 55 comprises a smooth inner wall configured for matching the top wall of the lodging. The inner ring blocks the overlapping gap in the outer ring.
Clause 17. The sealing ring can consist of two or more separate rings, e.g. concentric ring elements. The rings being configured so that, in use, a smooth outer surface of the inner ring is pushed against a correspondingly shaped, e.g. parallel smooth, inner surface of the outer ring to create a sealing. If provided the rings are longitudinally into sub-parts it is preferred that with said sub parts shifted with respect to each other so as to avoid an overlap. For example, the sub-parts of each ring are located at a different location (preferably opposite) such that the inner ring blocks the opening between the sub parts in the outer ring and the outer ring blocks the flow to the sub part in the inner ring.
| Number | Date | Country | Kind |
|---|---|---|---|
| 22290012.8 | Mar 2022 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2023/055187 | 3/1/2023 | WO |
