DE909134C - Method and device for the regeneration of dust-shaped fission catalysts - Google Patents

Description

Method and device for the regeneration of pulverized fission catalysis ators The invention relates to a method and a device for regeneration of dusty fission catalysts.

In this process, the solid catalyst is in finely divided form or powdered form, e.g. B. of such a particle size that the particles pass through openings of 0.15 mm sieve.

The regeneration gas is passed up through a bed of catalyst particles passed through at such a rate that this material is whirled up and takes on a liquid-like state. The gas flow that kicked it up Leaving bed carries with it a small amount of the solid particles in suspension (Loss of flight). This entrained amount increases with increasing gas velocity. It is common in the art to control the rate at which the gas escapes from the catalyst bed emerges, to be set in the order of magnitude of 0.15 to 0.6 m per second. the Bed density is determined by this. The height or depth of the fluidized bed is determined or determined by the contact time required for regeneration.

The only means of setting the desired throughput in a certain regeneration vessel consist in setting the horizontal Cross-sectional area of the fluidized bed and / or in the setting of the Pressure. In most cases the desired working pressure is dependent on other factors dependent, so that the cross-sectional area is the only variable to be set remains.

The horizontal cross-sectional area of the whirled up Bed is usually expressed in terms of the effective diameter of the bed. This is the diameter of a circle that has the same horizontal cross-sectional area like the bed thrown upside down.

So would a fluidized bed with a horizontal cross-sectional area of 9.3 square meters have an effective diameter of about 3.45 m, regardless of the Shape of the horizontal cross section.

The relationship between depth and diameter in the fluidized bed is advantageously smaller than I.

For example, the regenerator has a diameter of about I2 m. These boilers have the shape of vertical cylinders with conical upper ones and lower ends. The slope of the conical bottom part is slightly above the angle of repose of the catalyst. In a typical kettle, the conical portion is about one length of 6 m.

By introducing the regeneration gas at the bottom (at the top) of the The conical part of the boiler results in a strong distribution of the gas over the cross-sectional area of the swirled bed achieved. However, it cannot get a good distribution without a significant pressure drop, which is not caused by the conical part can be generated. In order to achieve a suitable distribution of the gas, the required pressure drop generated by using a multiple nozzle arrangement, as shown schematically in U.S. Patent 2,386,490. This arrangement however, was generally considered relatively ineffective, and in the newer systems will therefore reduce the required pressure drop through the use of a So-called. Grate, which is approximately at the level of the transition from the conical to the cylindrical section is placed across the boiler. Anyone can use the rust desired type. Usually, however, it consists of thick steel plates that have narrow bores, or from beams that are, for example, a width of 56 cm and spaced so that there are narrow slits between them are formed. The open area of the grate is less than Io 01o of the total area. As a result of the restriction of the flow of the gas flow, there is a strong pressure drop on the grate, and the bed of fluidized, finely divided solid matter remains during of working over the grate.

In the fluidized bed, the liquid-like powder is in the Violent agitation. When the beds are blown up, they are relatively large Relationship between depth and diameter is the ability to move horizontally limited by the boiler walls, and the possibility of significant local deviations of the average conditions is therefore minimal. When the beds are blown up, is Have a low ratio of depth to diameter, there is a possibility for horizontal movement, and a local deviation from the normal state can cause a bring about a relatively strong unidirectional flow. If so z. B. forms a local zone of low density as a result of the violent movement, the pressure drop through the bed is reduced instantaneously at that point.

This leads to an increase in the gas flow at this point At a bed that has a high depth to diameter ratio will be any such abnormal condition quickly eliminated by the violent agitation. In one On the other hand, a bed with a small ratio of depth to diameter can be such a zone, once it has developed, over a longer period of time over the cross-section wander of the bed before it is resolved. These relationships are particularly evident pronounced when the ratio of depth to diameter is less than I.

Such a zone often has the tendency to be relatively strong and at times to induce fairly constant, unidirectional circulation in the bed.

Attempts have been made to prevent such one-sided circulations, where they were suspected to be corrected by converting the distribution grate to the to counteract the so-called unidirectional circulation.

But this only shifted the course of this circulation. As far as is known, the only solution to the problem is to remove the whirled up To divide the bed into a number of smaller beds, e.g. B. U.S. Patent 2,359,310 is shown. But from a practical standpoint, this solution is for large vessels of the type in question not feasible, especially with regard to on the large pressure drops that occur.

It has now been found that the aforementioned difficulties in Regeneration of fission catalysts in the form of dust by means of a gas flow in one Bed of fluidized finely divided catalyst material with a ratio from height to diameter less than I that of a grate with less than 1001o open area is worn, can thereby be avoided or reduced that the gas flow is divided into a number without any significant pressure drop below the grate smaller streams divides that at least at three distant points 1.2 m below the grate, symmetrically inserted into the reaction vessel.

The various details of the procedure are given below explained in more detail in connection with the description of the device.

One form of suitable device is shown schematically in FIG. 1 shown. The figure is a side view (partially in section) of the here only eligible lower part of a fluidized catalyst working Regenerators.

The catalyst is not shown. In Fig. I the one is cylindrical Wall I of the boiler is only partially drawn. Below the cylindrical part is the usual conical section 2. A usual grate 3 is horizontal approximately in the Height of the connection between the cylindrical and the conical part across the boiler placed. The air for regeneration is supplied through line 4, which opens at the bottom of the conical part. According to the usual design, the line would 4 end approximately at the point where it joins the cone. The incoming air flows then up through the cone and is over by the pressure drop through the grille distributed across the cross section of the cylindrical portion. This pressure drop is usually on the order of 0.07 at. Around the small unevenness between the distances from the end of the line 4 to the center and to those at the periphery To compensate for lying parts of the grate, the open area of the grate sometimes becomes held somewhat larger near the circumference.

In the device shown in Fig. I, however, extends Line 4 into the conical part and divides there into a number of narrower ones Lines 5. These lines 5 together have a cross-sectional area that is approximately corresponds to the cross-sectional area of the line 4, and therefore do not cause any substantial Pressure drop. The lines 5 lead radially in the direction of spaced apart Surfaces of the grate, but open at a certain distance from them, as in the drawing is shown. The gas streams arrive at an angle Vertical near the grate. While you can get by with just three lines it is preferable to use one line for at least 14 square meters the grate surface. The lines can all be the same diameter or different Have diameter.

The lines 5 can be longer or shorter than in the drawing shown. But they must be of sufficient length to accommodate the To give direction to gas flows. It is not the purpose of the lines 5, the inflowing Blowing gas against different parts of the grate.

To prevent such an effect, remove the ends of the lines placed far enough below the grate to compensate for the kinetic To enable energy of the gas and a distribution of any solid particles that may be present. For this purpose, a distance of 1.2 m is sufficient in the normal case when the pressure drop due to the rust is of the order of 0.07 at and due to that in question Line system no significant pressure drop is caused.

The arrangement shown in Fig. I results in a substantial improvement compared to the conventionally built reaction vessel and has the advantage that it can be built into existing systems with a minimum of changes.

Another construction offering the desired advantages is in Fig. 2 shown. This figure, like FIG. 1, also represents a schematic one vertical section through the lower, here essential part of the contact chamber The device shown in FIG. 2 is essentially that shown in FIG similar, except that in place of the usual conical section a elliptical bottom is provided and the narrower lines 5 accordingly not are arranged inside, but outside of the boiler. This type has opposite the construction according to Fig. I three main advantages: I. Can with the elliptical Final floor easier and cheaper to build a boiler for higher pressure, 2. the dead space at the bottom of the conical section is avoided, 3. the Lines arranged outside the boiler with suitable flaps or regulators 7 equip which while working can be adjusted to a bad Improve distribution resulting from wear and tear of the grate or other Causes can develop.

The following example illustrates how the invention can be put into practice can be implemented without being construed as a limitation in any sense were.

Example A regenerator of a known type in one with a whirled up Catalyst working catalytic cracking unit had a cylindrical part 12 m in diameter and 10.5 m high as well as upper and lower conical sections about 5.7 m in length. The regenerator was equipped with a grate, which openings of 5 X 15 cm, the center lines of which were about 25 cm in one direction and about 25 cm in the perpendicular to this were about 60 cm apart. The open one The area of the grate was therefore about 3010 of the total area.

This regenerator worked smoothly and normally, as was evident a practically uniform oxygen content of the exhaust gas between about 1.5 01, and 2.0%.

There were specially constructed pegs through the outer steel wall and the inner refractory lining of the boiler passed through at various points and specially designed probes are used to take samples from different locations to be found in the swirled bed. It turned out that, although the conditions Considered in the regenerator as a whole, the conditions were essentially constant at one point fluctuated significantly, reflecting intermittent local (perhaps migratory) areas of low and high density.

The air supply was then extended up into the conical part in the form of nine radial pipes, which are 3.3 m below the floor surface of the rust ended. Four of the narrower tubes, which were offset from one another by go ", had a diameter of 60 cm, four others, which were also arranged symmetrically were, one of 35 cm. The ninth tube was 45 cm in diameter and was arranged vertically.

The cross-sections of the nine tubes together essentially corresponded the cross-section of the original supply line (150 cm in diameter).

After the regenerator was rebuilt in the specified manner, was the tendency for local abnormalities to form in the fluidized bed decreased, with the result of an increase in the overall effectiveness in terms of Regeneration, the z. B. was indicated by a decrease in the oxygen content of the Exhaust gas and an increase in the burning capacity of about 562 kg per hour. With this device can be operated satisfactorily with a pressure drop through the rust on the small order of just 0.035 at, reducing the cost of Forcing through the required large amounts of air can be significantly reduced.

For the reasons given, the method and apparatus are in accordance with of the invention as advantageous and useful only in such cases consider in which a substantial pressure drop is maintained across a grate which has an open area that is less than about IO <> I <> Olo of the total area around a gas flow in a whirled liquid-like Spreading bed of finely divided solids, the bed being a ratio has from depth to diameter below about I. In cases where this relationship above I, and in cases in which the contact zone above the grate has no contains solid bodies or is filled with solid bodies that have not been whirled up, z. B. with catalyst balls, the localized abnormal conditions of the described occur Kind of not up. If there is a bad distribution in such cases, it is attributable to other causes and permanent and requires other remedial measures.

Claims (5)

PATENT CLAIMS: 1. Process for regenerating dusty Fission catalysts by means of a gas stream in a bed of fluidized, finely divided Catalyst material with a height to diameter ratio less than I, which is supported by a grate with less than 10 ° / 0 open area, thereby characterized in that the gas flow is below the grate without any significant pressure drop is divided into a number of smaller streams, which are sent to at least three of each other distant points at least 1.2 m below the grate symmetrically into the reaction vessel to be introduced. 2. The method according to claim I, characterized in that the gas stream is guided upwards through a grate, which has a pressure drop of at least 0.035 at generated. 3. Apparatus for performing the method according to claim I or 2, characterized by a vertically arranged contact chamber, one horizontally arranged distribution grate with an open area less than In01 ,, a Supply line for the gas stream below the grate, a plurality of open ends Distribution pipes with a total cross-sectional area substantially equal to the cross-sectional area corresponding to the supply line, said distribution pipes from the supply line in the direction of different parts of the said grate, but the grate do not come closer than 1.2 m, and a floor below the grate and below of the open ends of said distribution pipes. 4. Apparatus according to claim 3, characterized by an elliptical Bottom through which the distribution pipes pass. 5. Apparatus according to claim 4, characterized in that the distribution pipes are equipped with regulators arranged below the floor. Attached publications: German patent specifications No. 444847, 498225 and 506544; Chemical Engineering Progress, Vol. 44 No. 7, July 1948, p. 5I2, 5I4 and 5I5; Engineering and Mining Journal, November 1947.