DE1088032B - Method and device for the treatment of finely divided solids in a fluidized bed - Google Patents

Description

Method and device for the treatment of finely divided solids in a fluidized bed The invention relates to a method and an apparatus for treating finely divided solids in a fluidized bed.

The invention is particularly useful in systems where a fluidizing gas with finely divided solids in two or more consecutive ones Layers is continuously brought into contact, with the exhaust gas from the in Direction of flow of solids seen last layer in a previous one Layer is used and solids from the last layer afterwards with one Come into contact with gas) that must be kept away from the layers. An example this is the direct reduction of iron ore, in which preheated iron ore is constantly is introduced into a first layer, where it is partially reduced, and from this into a second layer, where it is reduced more completely. Preheated Reducing gas (e.g. hydrogen) is constantly introduced into the second layer and from there it reaches the first layer in countercurrent to the flow of the ore. Reduced Iron powder is delivered from the second layer, usually in a stripping tower treated and compressed into briquettes. A stripping gas, such as nitrogen, comes into contact with the iron powder in the stripping tower to remove traces of the reducing gas to be removed There must be a seal between the stripping tower and the layers both to keep stripping gas away from the layers as well as reducing gas Gas from the Ahstreifturm.

A difficulty with devices of this type is that they become excessively high and therefore pose serious space and construction problems. That The height problem is most pronounced where the layers are arranged one above the other are, and such facilities usually extend to a height of about 60 m above the ground. If relatively coarse material (less than 9 or 6 mm) is treated, then the reactor containing the last layer usually has a floor outlet, preferably in the form of an overflow outlet, to collect to prevent coarse particles in the bottom of the layer. The floor outlet requires with a special dispenser to maintain a proper level of the layer and also to create a seal to allow gas flow between the following Treatment vessel (e.g. stripping tower) and the layer to be skinned The outlet, the dispensing device and the subsequent further treatment vessel require all an even greater height of the plant) when they are used to discharge the solids by gravity are set up.

The invention relates to a method and a device to save height, and is advantageous in systems where the height problem is the greatest Presents difficulties, d. H. where the layers are stacked. Despite such a device is generally preferred to those of higher altitudes in which the layers lie next to one another, since in the former the handling of the Materials is simplified. The procedure of the invention can also be based on Adjacent layer arrangements are used.

One known device for reducing the overall height is to that an intermediate standpipe between the floor drain and the stripping column is provided. The standpipe and the lower reactor form the arms of a U-shaped Tube, which creates static fluid pressure of solids in the reactor Forcing solid body to flow up the standpipe. The density of a mass A solid body held in suspension is in inverse proportion to that Superficial gas velocity. The surface gas velocity is the velocity meant with the gas supplied through the empty reactor or the standpipe would flow. If so, the suspended gas through the standpipe runs at a higher surface velocity than through the lower reactor, then the density of the layer in the reactor exceeds that of the column in the standpipe, whereby the column as a result of the liquid static pressure generated by the denser layer. is exerted, can reach a level even higher than the layer. This allows the lower reactor to be built closer to the ground, and by a distance that is approximately equal to the height of the column in the standpipe, and still discharge solids to the scraper. The total height of the plant decreases accordingly.

In the method according to the invention are used to treat the finely divided solid substances this continuously fed to a fluidized bed and out of it a vertical, suspended column of solids, which are under the influence .the liquid static pressure in the fluidized bed is raised, continuously withdrawn with gas pressure maintained over the top surface of the dispensing column which is lower than that in the fluidized bed by the height of the delivery column above the height Ztl, -which they raise under the influence of the liquid static Pressure alone.

The drawing shows, for example, a schematic vertical Section through a system according to the invention.

The drawing shows typical upper and lower reactors 10 and 12, which can be arranged within a common envelope. The upper reactor 10 has a horizontal perforated partition 13 which forms an upper fluidized bed A of the solid matter bears constantly by a usual, only shown schematically Inlet 14 are fed. The lower reactor 12 has a similar dividing tray 15, which carries a lower layer B, which is constantly due to the supply of solid particles is supplemented from the upper layer via a feed pipe 16. - Be solid fabrics continuously withdrawn from the lower layer through a flue pipe 17 located on the floor.

Fluidizing gas is constantly flowing to the lower reactor under its dividing tray 15 fed through an inlet pipe 18, and the ascending streams of this gas fluidize the layer B. Exhaust gas from the lower reactor enters the upper reactor under its partition plate 13 and fluidizes the layer A.

Exhaust gas from the upper reactor flows out through a pipe 19 and is in suitable Treated way depending on the operation. In the example of iron ore reduction, this gas is regenerated so that it can be reused in the reactors. Preferably the upper and lower reactors are provided with cyclone dust collectors 20 and 21, through which the gas flows out and the entrained solids are separated and they are returned to the appropriate layers.

A pipe 22 extends upwardly from the exhaust pipe 17 and leads to a standpipe 23> which can be an extension of the pipe 22 or how shown a vessel of enlarged cross-section.

Fluid static pressure of the lower layer B forces solid bodies, which are discharged from it, into the standpipe, where they form a column C. A dispensing tube 24 extends from said one.

Standpipe down and leads to a conventional stripping tower 25> which has a delivery tube 26. The column C represents a seal> around stripping gas to keep them from the shifts. Dispensing valves 27 and 28 are located in the dispensing tubes 24 and 26. These valves preferably work automatically.

As shown schematically in the drawing, the valve 27 is through a pressure difference between the free space of the lower reactor 12 and the lower SchictiSit located therein, 8 controlled (with p 1 and p2). In the same way, the valve 28 by the pressure difference between the free The space of the stripping tower 25 and the particles in it are controlled (with p3 and denoted p4). Solids discharged through valve 28 will be to any processing facility such as a briquetting machine in iron ore treatment.

The tube 22 has a gas inlet 29 and preferably at its lower end one or more intermediate gas inlets 30. fluidizing gas in communication with the gas coined, which is located in the reactors, is preferred through these gas inlets introduced into tube 22 in sufficient quantity to produce a superficial gas velocity in tubes 22 and 23 to maintain the superficial gas velocity goes out in the reactors. In this way, the static pressure of the fluid lifts the lower Layer B, supported only by a difference in density, fluidized solids in the standpipe at a higher level than the layer below Reactor. In the iron ore example, the gas entering the standpipe is preferred of the same composition as the reducing gas entering the lower reactor occurs, albeit at a lower temperature. The reactor gas is normally preheated to about 760 to 8710 C while the standpipe gas just passed through Pressure and heat exchange with exhaust gas from the upper reactor to a temperature is heated from about 149 to 5380 C.

The standpipe gas can also further reduce the contained therein Cause product. The greater tightness of the layer in the reactor compared to The density in the column of the standpipe also prevents gas from entering the inlet 29 runs to the exhaust pipe 17.

At the top of the tube 22 is preferably a normally open, manually operated shut-off valve 31 attached.

The pressure transmission line 32 is connected to the upper part of the standpipe 23 and connected to some part of the reduction system beyond the upper layer. In the illustration, the line 32 is directly into the free space of the upper reactor 32 introduced, although equivalent results can be obtained if the leadership at a more distant point on the pipeline that discharges the exhaust gas from this reactor, is connected. The gas above the upper layer A is on a lower one Pressure than that above the lower layer B as the pressure drops while the gas overcomes the resistance of the lower gas separators 21, the upper partition 13 and the top layer is formed. Accordingly, the upper part of the column is C. exposed to a lower pressure in the standpipe than the upper part of the lower layer B. This pressure difference forces column C to rise to a higher level, than by liquid static pressure, supported only by differences in density, can be reached.

Exhaust gas from the standpipe naturally flows through line 32 and 32 mixes with that from the upper reactor. Hence the need arises to use an inert gas in the standpipe. Preferably the standpipe contains a cyclone dust collector 33 through which the exhaust gas passes to remove entrained solids Separate particles and return them to the column.

As a particular example of the advantages that can be found in the way of working result according to the invention; a device is described which is used for serves direct reduction of iron ore. The device works with one layer in the lower Reactor that is 3.60 m deep and has a density of 31.78 kg / 0.028 m3, and one Column in the standpipe with a density of 28.3 kg / 0.028 m3. The pressure difference between the bottom of the lower layer and the free space above the upper layer (labeled p5 and p6) is approximately 0.7 kg / cm2. About 0.4 kg / cm2 of this The difference is due to the weight of the suspended solids in the lower layer and about 0.3 kg / cm2 due to the pressure drop that exists, while the gas overcomes the various resistances in its flow.

Liquid static pressure of the lower layer forces the column of the solids in the standpipe, to a height of 4 m (denoted by h 1) rise.

There is the following relationship: .. 1 h..h layer density column density X Layer depth The greater pressure on the surface of the lower layer forces the Column in the standpipe to rise an additional 2.90 m (labeled h2).

Additional height = pressure difference (kg / cm2) 144 additional height =. . . . 144.

Column tightness (g / cm5) Compared to an arrangement in which the Dispensing valves and the stripping tower under the lower reactor are located to remove solids by direct gravity flow can be the sum of the above Heights or approximately 7 m in height can be saved. So can the lower reactor around 7 m closer to the ground and the overall height is reduced accordingly.

PATENT CLAIM: 1. Process for the treatment of finely divided solids Substances in a fluidized bed, which is continuously supplied with solid substances and via a vertical, suspended column of solids, which are under the influence of the liquid static pressure in the fluidized bed is raised, continuously are withdrawn, characterized in that above the upper surface of the delivery column (C) a gas pressure is maintained which is lower than that in the fluidized bed, to the amount of To lift the delivery column (C) above the height which it is below the Influence of the liquid static pressure assumes alone.

Claims (1)

2. The method according to claim 1, characterized in that in arrangements with several fluidized beds the solids continuously from the last fluidized bed be withdrawn, the delivery pressure in the upstream ~ or overlying fluidized bed is lower than the pressure at the discharge point of the last fluidized bed and the lower pressure on the upper surface of the dispensing column that preceding the dispensing zone Fluidized bed is taken. 3. The method according to claim 2, characterized in that in the Dispensing column (C) a fluidizing gas is introduced, which is opposite to that of the upper Surface of the delivery column (C) polluting gas from the penultimate zone is inert. 4. fluidized bed reactor for carrying out the method according to claim 1 to 3, consisting of two fluidized bed chambers arranged one above the other with one Inlet for the solids, which opens out above the upper layer, a pipe to discharge the substances from the upper to the lower layer and an inlet for fluidizing gas flowing in opposite to the flow of solids below the lower layer and a standpipe outside the lower reactor, which connects the lower end of the reactor with a separation tower, characterized in that that the head of the standpipe (23) through a line (32) with the space above the upper Fluidized bed (A) is connected. 5. Apparatus according to claim 4, characterized in that the standpipe (23) connected at its lower end to a feed line for the fluidizing gas is. 6. Apparatus according to claim 4, characterized by an outlet valve (27) on the standpipe (23), which is caused by the pressure difference in and above the fluidized bed (B) is controlled in the lower reactor (12). 7. Apparatus according to claim 4, characterized by an outlet valve (28) on the separation tower (25), which is caused by the pressure difference between the free Space above the column of solids in the separation tower and controlled in the column will.