GB2406802A - Reactor incorporating a filter system - Google Patents

Abstract

A reactor incorporating a filter system comprises a reactor vessel (3) having a first end (5) and a second end (7). A body of catalytic material (9) and at least one layer of filter material (11) is provided within the reactor vessel (3). The filter system is arranged such that a stream of gas entering the reactor vessel (3) at the first end (5) passes through the at least one layer of filter material (11) and the body of catalytic material (9) prior to the gas exiting the reactor vessel at the second end (7). The filter layer may be before or after the catalytic material and may comprise a pluraty of sections adjacent to each other. The filter material is in the form of a paper, felt, board, or blanket and is composed of refractory fibres chosen from metal, mineral wool or ceramic fibres. The catalytic material may be granular, monolithic or mesh form.

Description

REACTOR INCORPORATING A FILTER SYSTEM

This invention relates to a reactor incorporating a filter system, in particular a filter system comprising catalytic material.

It is known in high temperature, gas phase reactor vessels to use catalytic material to speed up reactions or increase reaction yields. For example a V2O5 catalyst is used to oxidize SO2 to SO3 at approximately 400 degrees Celsius, in the production of sulphuric acid, and a platinum/rhodium catalyst is used for the oxidation of NH3 at approximately 800 degrees Celsius, in the formation of nitric acid.

Typically, catalytic material is in the form of granules, although catalytic materials in the form of monolithic ceramics and metallic meshes are also known. The catalytic material is typically arranged in the form of a fixed bed of solid catalytic material through which gases are passed.

Often, a reactor vessel is arranged such that gas is passed vertically down through the catalyst bed. In such a case, if the gas contains particulate material, the particulate material will accumulate on the upper face (inlet) of the catalyst bed. The particulate material can also accumulate within the body of the catalyst bed.

In many cases, the gases used in gas phase reactor vessels are generated hot. It is both a waste of energy and time consuming to cool the gases to enable solid particles present within a gas stream to be removed. Means provided externally to the reactor vessel, for example electrostatic precipitators, can be used which remove the particulate material from gases at high temperature. However such means can suffer from relatively poor efficiency and/or breakthrough.

Generally, the size of the particulate material contained within a gas stream is relatively small and consequently the particulate material can relatively quickly accumulate and pack together on the inlet, and within the body, of the catalyst bed. As a result, the pressure required to force the particulate material through the catalyst bed increases rapidly. Normally, there is access to the inlet of the catalyst bed to enable the removal of the accumulated particulate material. However, in order to gain access the reactor vessel must be shut down.

One method of removing the accumulated particulate material from the inlet of the catalyst bed is by means of vacuuming the surface of the catalyst bed. However, this method is relatively inefficient and eventually the catalyst bed must be removed and cleaned, for example by sieving. l. - 3

In some reactions, for example during the oxidation of SO2 to S03, it is important that particulate material, for example arsenic, should not come into contact with the catalyst bed as it can poison the catalytic material.

There is, therefore, a demand for a system which overcomes these various disadvantages.

It is an object of the present invention to provide a filter system to minimise or prevent the accumulation of particulate material in contact with the catalytic material.

According to the present invention there is provided a reactor incorporating a filter system and comprising: a reactor vessel having a first end and a second end; a body of catalytic material provided within the reactor vessel; and at least one layer of filter material provided within the reactor vessel; wherein the filter system is arranged such that a stream of gas entering the reactor vessel at the first end passes through the at least one layer of filter material and the body of catalytic material prior to the gas exiting the reactor vessel at the second end.

I. b, - 4 - The at least one layer of filter material may be provided between the first end of the reactor vessel and the body of catalytic material. The at least one layer of filter material may be in contact with the catalytic material.

Alternatively, the at least one layer of filter material may be supported a distance away from the catalytic material between the body of catalytic material and the first end of the reactor vessel.

The at least one layer of filter material may comprise fibres, processed into a planar form, for example as paper, felt, board or blanket.

The fibres may have a nominal diameter in a range from 1 micron to 10 micron, preferably in a range from 1 micron to 4 micron.

The fibres may be refractory fibres, for example refractory metal fibres, mineral wool and/or ceramic fibres.

The ceramic fibres may be blown, spun or extruded ceramic fibres.

The ceramic fibres may comprise alumina nominally in a range from 30 to 97 per cent by weight, and silica nominally in a range from 3 to 70 per cent by weight. e - 5

The at least one layer of filter material may comprise a plurality of sections, preferably in a co-planar arrangement and adjacent to one another.

The at least one layer of filter material may comprise a plurality of layers of filter material superimposed on top of one another.

The at least one layer of filter material may be disposable.

The body of catalytic material may have granular form, be a monolithic ceramic or have a mesh form, for example a metal mesh form.

For a better understanding of the present invention and to show more clearly how it may be carried into effect reference will now be made, by way of example, to the accompanying drawings in which: Figure 1 is a cross-sectional view of a first embodiment of a filter system in accordance with the present invention; Figure 2 is a plan view of one embodiment of a layer of filter material of the filter system in Figure 1; - 6 - Flqure 3 is a cross-sectional view of a second embodiment of a filter system in accordance with the present invention; Figure 4 is a cross- sectional view of a third embodiment of a filter system in accordance with the present invention; and Figure 5 is a cross-sectional view of a fourth embodiment of a filter system in accordance with the present invention.

Figure 1 shows a filter system 1 comprising a reactor vessel 3 having an elongate cylindrical body. The reactor vessel 3 has a first end 5 and a second end 7 and contains therein a body of catalytic material 9 and a layer of filter material 11.

The catalytic material 9 is supported from beneath by an arrangement of ceramic and/or metal beams 13 attached to the reactor vessel 3. The catalytic material extends substantially across the full internal crosssectional area of the reactor vessel. The catalytic body comprises a granular catalyst arranged in the form of a fixed body of solid material. - 7

The layer of filter material 11 is provided directly onto the uppermost surface of the catalytic material 9 covering substantially the full surface area of the catalytic material 9.

The layer of filter material is in the form of a planar felt of ceramic fibres, the fibres being nominally in a range from 1 to 10 micron in diameter, and preferably in a range from 1 to 4 micron in diameter.

The ceramic fibres can be made by spinning, blowing or extrusion methods as known to a person skilled in the art.

The ceramic fibres typically comprise alumina in a nominal range from 30 to 97 per cent by weight, and silica in a nominal range from 3 to 70 per cent by weight.

In use, a stream of high temperature gas is passed under pressure into the reactor vessel via the first (upper) end 5. The gas passes through the layer of filter material and into the body of catalytic material before exiting the reactor vessel via the second (lower) end 7. As the gas passes through the catalytic material, the gas and catalytic material react to produce desired gaseous reaction products. 8 -

The layer of filter material acts as a barrier which substantially prevents particulate material entrained in the gas stream from coming into contact with the catalytic material and accumulating in contact with the catalytic material. As such, particulate material which can poison and destroy a catalytic material, for example arsenic in the sulphur dioxide process, cannot come into contact with the catalytic body, thus preventing damage.

When the pressure drop across the layer of filter material increases to an unacceptable value due to the accumulation of the particulate material on the layer of filter material, the reactor vessel can be shut down and the existing layer of filter material can be removed and replaced by a new layer of filter material.

Provided in the wall of the rector vessel is an openable aperture (not shown), for example a manway of nominally 600 mm diameter, through which a person can enter the reactor vessel. The reactor vessel is also provided with some freeboard, nominally 150 to 300 mm, between the top of the catalytic material and the aperture.

It is therefore possible for a person to completely enter the reactor vessel to replace the layer of filter material. i - 9 -

However, such an action is potentially unsafe and should be avoided where possible.

Therefore, by using the aforementioned aperture a person positioned substantially outside the reactor vessel can remove and replace an existing layer of filter material.

The existing layer of filter material can be rolled up, preferably placed in a container to prevent exposure to the accumulated particulate material, and removed without the need to completely enter the reactor vessel. A new layer of filter material can be placed in position on the surface of the catalytic position in a rolled, pleated, folded or furled form and then opened out into position. By means of the use of elongate tools, the layer of filter material can be positioned as required by the person positioned outside the reactor vessel.

If the cross-sectional area of the reactor vessel is too large for the positioning of a single piece layer of filter material, the layer of filter material can be made up of sections (11') of filter material, for example in the form of strips, unrolled individually and positioned substantially in contact adjacent to one another to cover substantially the full surface area of the catalytic material, as shown in Figure 2. i.

Although a filter system in accordance with the present invention has been described in which a single layer of filter material is positioned on the catalytic material, it should be appreciated that a plurality of layers of filter material could be provided, for example, between the first end of the reactor vessel and the catalytic material, as shown in Figure 3. When the layer closest to the first end of the reactor is causing an undesirable pressure drop within the system it can be removed to reveal a lower layer of filter material which does not have an accumulation of particulate material on its surface. In this way it is possible to regenerate a desirable pressure drop across the filter material. Ideally, the removal of the layer of filter material closest to the first end of the reactor would be carried out without the need to shut down the reactor vessel.

Although the layer of filter material has been described as being in contact with the body of catalytic material, it should be appreciated that, for example as shown in Figure 4, at least one layer of filter material could be provided between the body of catalytic material and the first end of the reactor vessel but be supported a distance away from the catalytic material. - 11

Although the layer of filter material has been described as being in the form of a ceramic felt, it should be appreciated that other planar forms, for example of paper, board or blanket forms of ceramic fibres may be used. It should also be appreciated that other types of fibre, for example refractory metal fibres and/or mineral wool, can be used to form the layer of filter material. The fibres required to form the layer of filter material preferably need to be resistant to, for example, high temperatures, chemically active gases and/or chemically active liquids.

It should also be appreciated that, for example as shown in Figure 5, at least one layer of filter material could be provided within the body of the catalytic material, for example where contact between the particulate matter within a stream of gas and the catalytic material would not lead to the poisoning of the catalytic material. Such a layer of filter material within the catalytic body would be arranged to trap any particulate material that does enter the catalytic body and substantially prevent the particulate material passing completely through the catalytic body.

It should also be appreciated that, although the figures show the filter vessel in a substantially vertical arrangement, a filter system in accordance with the present - 12 invention could comprise a reactor vessel arranged in a variety of orientations.

Claims (23)

1. A reactor incorporating a filter system and comprising: a reactor vessel having a first end and a second end; a body of catalytic material provided within the reactor vessel; and at least one layer of filter material provided within the reactor vessel; wherein the filter system is arranged such that a stream of gas entering the reactor vessel at the first end passes through the at least one layer of filter material and the body of catalytic material prior to the gas exiting the reactor vessel at the second end.

2. A reactor as claimed in claim 1, wherein the at least one layer of filter material is provided between the first end of the reactor vessel and the body of catalytic material.

3. A reactor as claimed in claim 1 or 2, wherein the at least one layer of filter material is in contact with the catalytic material.

4. A reactor as claimed in claim 1 or 2, wherein the at least one layer of filter material is supported a distance away from the catalytic material between the body of - 14 catalytic material and the first end of the reactor vessel.

5. A reactor as claimed in any preceding claim, wherein the at least one layer of filter material comprises fibres, processed into a planar form.

6. A reactor as claimed in claim 5, wherein the planar form is as paper, felt, board or blanket.

7. A reactor as claimed in claim 5 or 6, wherein the fibres have a nominal diameter in a range from 1 micron to micron.

8. A reactor as claimed in claim 7, wherein the fibres have a nominal diameter in a range from 1 micron to 4 micron.

9. A reactor as claimed in any one of claims 5 to 8, wherein the fibres are refractory fibres.

10. A reactor as claimed in claim 9, wherein the refractory fibres are refractory metal fibres.

11. A reactor as claimed in claim 9 or 10, wherein the refractory fibres are mineral wool fibres.

12. A reactor as claimed in claim 9, 10 or 11, wherein the refractory fibres are ceramic fibres.

13. A reactor as claimed in claim 12, wherein the ceramic fibres are blown, spun or extruded ceramic fibres.

14. A reactor as claimed in claim 12 or 13, wherein the ceramic fibres comprise alumina nominally in a range from to 97 per cent by weight, and silica nominally in a range from 3 to 70 per cent by weight.

15. A reactor as claimed in any preceding claim, wherein the at least one layer of filter material comprises a plurality of sections.

16. A reactor as claimed in claim 15, wherein the plurality of sections are in a co-planar arrangement and adjacent to one another.

17. A reactor as claimed in any preceding claim, wherein the at least one layer of filter material comprises a plurality of layers of filter material superimposed on top of one another.

18. A reactor as claimed in any preceding claim, wherein the at least one layer of filter material is disposable. - 16

19. A reactor as claimed in any preceding claim, wherein the body of catalytic material has granular form.

20. A reactor as claimed in any one of claims 1 to 18, wherein the body of catalytic material is a monolithic ceramic material.

21. A reactor as claimed in any one of claims 1 to 18, wherein the body of catalytic material has a mesh form.

22. A reactor as claimed in claim 21, wherein the mesh form is a metal mesh form.

23. A reactor incorporating a filter system being substantially as hereinbefore described with reference to, and as shown in, the accompanying drawings.