EP0126001A1 - Process and apparatus for the treatment of fuel in a fluidized bed - Google Patents

Abstract

1. Process for a fluidized bed treatment of a fuel in a plant comprising a vertical reaction chamber (1) provided at its base with means (14) for feeding fuel and means (11) for fluidizing by injecting a gas and whose upper end is connected by a gas exit duct (12) to a device (2) for recovering the entrained solid particles comprising an exit orifice (21) for the gases and an exit orifice (22) for the solid particles which are connected by a recycling circuit (23) to the base of the reaction chamber (1), characterized in that, with the nature of the fuel and the operating conditions, such as the shape and the dimensions of the plant, the particle size measurements of the particles and the gas circulation velocities, being taken into account : - a reference temperature is determined, above which the stationary solid particles are liable to adhere to each other inside the recovery device (2), - the fluidization conditions are adjusted to produce a circulating bed regime in the plant, - the reaction temperature in the dense part (15) of the fluidized bed is adjusted to a level above the reference temperature, - the average temperatures are measured in a plurality of temperature control zones (A, B, C, D, etc) placed at intervals in the direction of travel of the gases and of the solids inside the plant, - each measured temperature is compared with the determined reference temperature, and - a lowering of the average temperature is produced locally in any one zone, upstream of the recovery device (2) each time the temperature measured therein reaches the reference temperature, in order to keep the average temperature in each zone continually below the corresponding reference temperature.

Description

The subject of the invention is an improved process and installation for treating a combustible material in a fluidized bed, applicable in particular to the gasification of coal.

A granular material processing installation in a fluidized bed normally consists of a vertical reaction chamber supplied with granular combustible materials and provided at its base with means for injecting a fluidizing gas whose circulation speed can be regulated in acting on the injection rate.

At its upper part, the reaction chamber opens into a smoke evacuation circuit which includes a gas outlet pipe opening into a device for recovering solid particles entrained with the gases. This recovery device can for example be a cyclone which comprises an upper orifice for leaving gases and very fine particles and a lower orifice for leaving solid particles having a dimension greater than a certain limit which depends on the performance of the recovery device. The solid particles thus recovered are returned to the fluidized bed, at the base of the reaction chamber, by a recycling circuit. In this way, the incompletely burned particles are recycled at the base of the reaction chamber, in the combustion zone, the fumes causing only the finest ashes.

It is known that the operating mode of the fluidized beds is linked to the injection rate and to the gas circulation speed. If the injection rate is adjusted so that the gas speed is only a little higher than the critical speed from which fluidization begins, most of the solid particles remain at the base of the reaction chamber under form a dense fluidized bed, only very fine particles being entrained with the gases. On the other hand, if the fluidization speed exceeds a limit which depends on the average particle size and which is of the order of 4 m / s, most of the particles are entrained with the fumes and a distinction is made then inside the reaction chamber a dense lower zone surmounted by a dilute zone traversed by an ascending current of gases and particles which escapes by the outlet pipe, the solid particles being separated from the gases in the device recovery and returned to the dense area of the fluidized bed, at the base of the reaction chamber, by the re cycling. We then have a so-called running bed operation.

Circulating fluidized beds have a number of known advantages. In particular, they allow greater power than ordinary dense beds, the volume of the combustion chamber being better used since the reaction can take place not only in the dense bed, at the bottom of the reaction chamber, but also in the diluted area. The circulating beds are also more flexible because they make it possible to vary the speed of the gases, and to adjust the rate of circulation therefore the residence time of the fuel. However, the efficiency of a combustible material treatment installation and in particular of a gasification installation depends on the average residence time of the particles which must be greater than the gasification time, the latter depending on the nature of the fuel and the average particle size. It is obvious in particular that if the combustion or gasification time is too long, the fluidized mass increases and the limit level of the dense zone will rise, which means that the rate of supply of combustible material must be reduced to the benefit of use a tall reaction chamber to absorb variations in the limit level.

To reduce the gasification time, one can play on the particle size and the reaction temperature. However, it is known that by increasing the reaction temperature, there is a risk of reaching a temperature from which the particles and in particular the ashes stick to each other and to the walls of the installation, which risks causing blockage. of it. This bonding temperature depends on the nature of the material, its particle size and the operating conditions. is lying. In fact, it has been observed that the risk of sticking is less significant in the areas where the particles are subjected to significant agitation and relatively spaced from one another. On the other hand, bonding takes place more easily in dense areas, in particular when the particles are stationary, and this is the case of the device for recovering solid particles which can thus be easily blocked.

In the operation of treatment and in particular gasification installations, there is therefore a division between the desire to increase the reaction temperature as much as possible to reduce the gasification time and the risk of particle sticking.

When using a fluidized bed at low speed, the high temperature zone is limited m dense fluidized bed or one can reach a temperature from which the ash gradually agglomerates is lying. This has the advantage of allowing the evacuation of the ash which has formed blocks of a certain size and which can be removed by a purge placed at the base of the reaction chamber. However, in a fluidized bed at low speed, the homogenization of the temperatures may not be effective enough to avoid localized overheating and we therefore arrive in certain regions at a melting of the ashes which can go as far as blocking the reactor.

To reduce the risk of merging. ash at high temperature, it is therefore advantageous to increase the speed of circulation of the gases and one arrives at a functioning in circulating bed which, as indicated, allows to increase the power of the installation for a size given. However, when operating in a circulating bed, precisely because of the continuous circulation of most of the solid particles, the temperature is practically the same in all parts of the installation. However, the risk of sticking is greater in certain areas, in particular in the connecting pipes and especially in the recovery device where the particles are practically stationary and form a dense bed. Consequently, even when operating in a circulating bed, it is necessary to limit the reaction temperature.

The invention relates to a new method for operating in a circulating bed at the highest possible temperature so that the particles remain as long as possible at this high temperature without risk of sticking.

According to the invention, taking into account the nature of the combustible material and the operating conditions such as the shape and the dimensions of the installation, the particle size and the gas circulation speeds, a temperature of reference from which the particles of immobile material are likely to stick to each other inside the recovery device, the fluidization conditions are adjusted to achieve operation of the installation in a circulating bed, regulates the reaction temperature in the dense part of the fluidized bed to a level higher than the reference temperature and a controlled cooling of the particles of material is produced upstream of the recovery device, capable of maintaining the temperature inside of it at a level below the reference temperature.

Thus, while in a circulating bed, the temperature is relatively homogeneous over the entire circuit of materials, in the process according to the invention, it is possible to have a high temperature up to the inlet of the recovery device and to produce at this time the cooling necessary for lowering the temperature of the particles below the level for which their bonding could occur. moment when the particles are packed and relatively immobile with respect to each other. This cooling does not significantly decrease the yield of the reaction since the high temperature is maintained not only in the dense area of the fluidized bed but also in the diluted area. The reaction can thus take place as long as possible at high temperature, the risk of sticking being less in the zones where the particles are in agitation and separated from each other.

In this way it is therefore possible to adjust the reaction temperature to the highest possible level and in particular to a level allowing the agglomeration of the ash into blocks capable of being removed by known means, without however reaching the melting temperature which would risk cause a blockage of the reactor.

As indicated, the bonding temperature depends on the operating conditions and therefore, having observed these, it will be possible to determine in each zone of the installation, according to the circumstances specific to this zone, the temperature limit at not to exceed.

This is why, in a more sophisticated embodiment, the installation is divided into a plurality of zones (A, B, C, D, etc.) for controlling the temperatures staggered in, the direction of circulation of the gases and materials, the average temperatures in each zone are measured, each temperature measured is compared to a reference temperature determined according to the operating conditions specific to the zone considered and a local production is carried out in one or the other zone. lowering of the average temperature each time the measured temperature reaches the reference temperature therein, so as to keep the average temperature in each zone permanently below the corresponding reference temperature.

According to the constructive characteristics of each installation, it will be possible to control the whole of it or else certain well-chosen zones. In general, the temperatures will preferably be controlled in at least one zone A at the bottom of the reaction chamber, that is to say in the dense zone of the fluidized bed, a zone B slightly above the level limit of the dense zone, a zone C in the diluted zone, at the top of the reaction chamber and a zone D just upstream of the recovery device.

To achieve a local temperature reduction in the chosen zone, a cold product in divided form will be injected into it, which may consist, for example, of water spray or steam, of particles recovered and cooled before being recycled in the fluidized bed or by a part of the gas produced, taken at the outlet of the recovery device and recycled in the desired zone after cooling. However, the cold product injected can also consist of at least part of the combustible material introduced at the top of the diluted zone into the reaction chamber with an adjustable flow rate so that the coarsest particles fall into the dense zone. from the fluidized bed by crossing the diluted zone, the finest particles being entrained with the fumes towards the recovery device and then recycled in the fluidized bed.

The invention also covers an improved installation for processing combustible material, conventionally constituted by a reaction chamber in a fluidized bed connected to a circuit for recovering and recycling solid particles entrained with the fumes and comprising a localized cooling means. materials entrained with the flue gases, placed upstream of the recovery device and a means of controlling the intensity of cooling as a function of the temperature of the materials accumulated in the recovery device, for keeping them below d '' a chosen reference temperature.

A plurality of temperature control zones (A, B, C, D, ...) can be distinguished inside the installation, staggered in the direction of flow of gases and materials and each covering the entire section transverse gas passage at the level considered; each control zone is provided with a means for measuring the average temperature and with a cooling means capable of causing a localized lowering of this temperature in the zone in question, the means for temperature measurement and cooling of the control zones being associated with a regulation device which comprises a set of comparators of the temperatures measured with reference temperatures determined as a function of the operating conditions desired in each control zone, a set of members for adjusting the cooling means and a means of control of the regulating devices as a function of the differences observed between the measured temperatures and the reference temperatures.

But the invention will be better understood by referring to a mode of particular embodiment, given by way of example and shown in the accompanying drawing.

The single figure schematically represents a gasification plant for coal in a fluidized bed provided with improvements according to the invention.

The gasification installation essentially comprises a reaction chamber 1 in the form of a column, consisting of an elongated cylindrical enclosure with a vertical axis provided at its base with a grid for the homogeneous distribution of a fluidizing gas introduced below the grid with a flow rate adjustable by injection means (11). The reaction chamber (1) is connected at its upper part, by a flue outlet pipe 12, to a device 2 for recovering the entrained solid particles, for example a cyclone deduster comprising an upper outlet 21 for the gases and an outlet lower 22 of the recovered particles which opens into a recycling pipe 23 connected to the base of the chamber 1 by a device for reinjection of solid particles consisting for example of a siphon 24 into which a gas can be injected allowing the regulation of the reinjection rate.

The combustible material, stored in a hopper 13, is introduced at the base of the combustion chamber, into the fluidized bed, for example by means of a screw feed device 14 making it possible to adjust the feed rate by acting on the speed of rotation of the screw. In addition, a purge line 17 placed at the lower end of the combustion chamber 1 makes it possible to remove the agglomerated ash.

Of course, the entire installation, but especially the walls of the combustion chamber are coated with a refractory and insulating coating.

The flow rate of the fluidizing gas injection member 11 is adjusted so that the installation operates in a circulating bed, the gas circulation speed being greater than 4 m / s so that the gases entrain the greater part of the solid particles which then occupy the entire height of the column 1 inside which there is a lower zone 15 in the dense phase and an upper zone 16 in the diluted phase. In practice, the combustible material introduced into the chamber (1) is divided into two parts: the finest particles are immediately entrained with the gases while the largest particles fall into the dense zone 15 and remain there until the moment where, after partial combustion, they reach a dimension which allows them to be in in turn. The dense zone may also contain an inert granular material which supports the fluidization or which has a role in the reaction.

The solid particles entrained in the outlet pipe 12 are stopped in the collector 2 and then recycled to the fluidized li _t via line 24.

One can distinguish in the installation a certain number of zones staggered in the direction of circulation of gases and particles, and for each of which it is possible to define an optimal temperature which depends on the operating conditions prevailing in the zone considered.

The dense area of the fluidized bed contains the largest particles of fuel and inert material and is traversed by the recycled fine particles consisting of incompletely burnt material and ash. It is desirable to maintain in this zone a temperature for which the ashes are sufficiently softened to allow their agglomeration while avoiding their fusion or solidification. In fact, by agglomerating, the ash forms blocks that are easier to remove, but too high a temperature rise could cause the ash to melt and stick together between them and on the walls of the reactor with the risk of blocking it.

In the diluted zone 16, the solid particles carried away by the gaseous fluid are found at substantially the same temperature as in the dense zone 15 and are therefore agglomerating; their concentration being lower and their agitation important, the tendency to agglomeration is less but it is still necessary to avoid the sticking of the particles on the walls of the reactor in particular in the critical zones which it is possible to locate.

This risk of sticking to the walls is even greater in the separator 2 because of the effect of the centrifugal force which presses the ashes against the walls and the fact that the solid particles are packed there and practically immobile with respect to the others before being returned to the reaction chamber by circuit 24.

It is possible, by calculation and, to a certain extent, empirically, to define for each zone the optimal operating temperature which must be brought as close as possible to obtain good agglomeration but without exceeding it to avoid the melting of the ashes. On the other hand, a number of temperature sensors 31, 32, 33, 34 can be placed in the most sensitive parts of the installation. So in the embodiment shown in the figure, a sensor 31 was placed in the center of the dense area 15, a sensor 32 at the bottom of the diluted area 16, slightly above the limit level of the dense area, a sensor 33 at the upper end of the reaction chamber 1, near the outlet flue and a sensor 34 at the inlet of the recuperator 2 near the wall.

The set of sensors is connected to a measuring device 3 providing at its output signals corresponding to the temperatures measured by each of the sensors, which are applied to a set of organs 4 ₁ , 42, 43, 44 for comparing each signal temperature with a displayed signal corresponding to the reference temperature determined for the zone considered.

On the other hand, in each zone, there is a localized intervention means making it possible to rapidly decrease the temperature of the zone considered as soon as an excessive rise in temperature is detected. This intervention means consists, in the example shown, of a cooling circuit 5 comprising a fan 51, the supply line 52 of which is connected to the sheath 26 of the gas outlet from the separator 2 in order to take off part of the evacuated gases, these having preferably been cooled by means of an exchanger 27 placed on the outlet sheath 26 upstream of the supply line 52. The discharge line 5 of the fan 51 is divided into a number of branches 6 provided at their ends with injectors 61, 62, 63, 64, opening into the various zones of the installation, substantially at the height of the corresponding temperature sensor. It is also possible, if necessary, to provide each branch of injection 6 with a plurality of injectors distributed regularly in a plane transverse to the axis so that the injected cooling fluid is spread evenly. throughout the cross section of the installation at the height of the area considered. Given the homogenizing effect of the temperatures obtained in addition by the use of a high fluidization speed, it will thus be possible to control the temperature fairly precisely inside each zone of the installation, on the entire cross section of the gas passage.

To this end, each branch 6 of the cooling circuit will be provided with a valve (71, 72, 73, 74) controlled by a computer 7 as a function of the temperature differences measured by the comparators 41, 42, 43, 4 ₄ . Of course, the computer 7 is programmed so as to take account of the interactions between the zones, any cooling in an zone having repercussions in the following areas. There is thus a flexible and precise means of controlling the temperature in the various zones of the installation, making it possible to avoid localized overheating with melting of the ashes and risk of sticking to the walls, taking account of the proper operating conditions. to each zone and in particular of the gas passage section, the particle size and the density of the solid particles. If necessary, one could obviously increase the number of control zones and in particular place several temperature detectors and several cold fluid injectors staggered over the entire height of the diluted zone 16 of column 1.

In the example shown, the temperature control of the different zones is obtained by injecting a portion of the fumes sampled at the outlet of the separator, after cooling to a temperature below ambient temperature in the different zones of the installation. One could however inject another fluid cooling agent such as steam or water spray, obviously taking into account the influence of such an injection on the thermal balance. However, it is also possible to inject finely pulverized solid particles so as to spread quickly in the control zone. This is the case, in particular, of the solid particles retained by the separator 2 and recycled in the fluidized bed by the circuit 23. The latter could for example be provided with an exchanger 28 making it possible to reduce the temperature of the recycled particles to desired level. In this case, one acts directly on the temperature existing in the fluidized bed, the recycled particles being immediately distributed in the zone 15 by the turbulence effect produced by the fluidization but, one can also take a certain flow of particles on the pipe. recycling 23, downstream of the exchanger 28, to reintroduce them by appropriate means in other areas of the installation.

The system which has just been described therefore makes it possible to control the temperatures throughout the installation and the nature of the injected cooling product can be determined as a function of the zone on which it is desired to act and of the desired effect.

Thus, at the bottom or in the center of zone 15 of the fluidized bed, solid particles or water are preferably injected in the gas or liquid phase to control agglomeration.

At the height of the separation surface of the dense zone and the diluted zone, to avoid sticking of the ashes on the walls, we will inject, at 62, recycled particles, water or part of the pre-fumes lifted after cooling and recycled by circuit 5.

At the exit from the dense zone 16, in the connection line 12 or at the entrance to the separator 2, water or recycled gas will be infected, by the injectors 63 or 64, to avoid sticking and accumulation in the separator. To modify the temperature in the desired direction, it is obviously possible to use the injections individually or in combination with one another, by acting either on the flow rate injected if the cooling agent is a gas or water spray, or, preferably, on the temperature if the coolant consists of recycled solid particles.

In a particular embodiment, it is also possible to use as a cooling product part of the fuel withdrawn from the supply circuit thereof and injected at 17, preferably at the top of the diluted zone 16.

The large particles fall directly into the dense zone 15 and the fines are carried directly to the separator 2 via the outlet pipe 12. This introduction of cold fuel into the diluted zone 16 which is below the stoichiometry therefore causes a lowering of temperature in the injection zone not only due to the introduction of a cold product but also by the effect of the endothermic reaction of elimination of the volatile materials contained in the coal in contact with the hot gases. In this way, in addition to cooling, a secondary degassing effect of the coal is obtained which makes it possible to reduce the risk of agglomeration. This pre-treatment can be useful for certain agglomerating coals which are difficult to treat in a fluidized bed. In addition, this increases the methane content of the gas produced and therefore its calorific value which is advantageous when the gas produced is used as fuel.

Of course, the installation according to the invention has only been described schematically, the devices used such as the regulation system and the means for cooling and injecting the recycled product can be produced with known means. In general, the invention could be the subject of variants and improvements, and, for example, the reaction chamber could be divided into a greater number of temperature control zones staggered from bottom to top to 1 inside the dense zone and especially in the diluted zone of the fluidized bed.

Claims (15)

1.- Method for treating a combustible material in a fluidized bed in an installation comprising a reaction chamber (1) supplied with combustible material, provided at its base with means (11) for injecting a fluidizing gas and opening out at its upper part in a smoke evacuation circuit (12) comprising a device (2) for recovering solid particles entrained with the gases, connected to the reaction chamber (1) by a circuit (23) for recycling the particles recovered, characterized in that, taking into account the nature of the combustible material and the operating conditions, a reference temperature is determined from which the particles of immobile material are liable to stick to each other at the inside the recovery device (2), the fluidization conditions are adjusted to achieve an operation of the installation in a circulating bed, the temperature of the reaction in the dense part (15) is adjusted of the fluidized bed at a level higher than the reference temperature and a controlled cooling of the particles of materials is produced upstream of the recovery device (2), capable of maintaining the temperature inside the latter at a level lower than the reference temperature. 2. A treatment method according to claim 1, characterized in that the reaction temperature in the dense part (15) of the fluidized bed is adjusted to a level allowing the agglomeration of the ashes into blocks capable of being removed. . 3.- Method for treating a combustible material in a fluidized bed in an installation, comprising a vertical reaction chamber (1), provided at its base with means (14) for supplying combustible material and means (11) for fluidization by injection of a gas and the upper end of which is connected by a gas outlet pipe (12) to a device (2) for recovering entrained solid particles comprising a gas outlet orifice (21) and an orifice (22) outlet of the solid particles connected by a recycling circuit (23) to the base of the reaction chamber (1),
characterized by the fact that the installation is divided into a plurality of temperature control zones (A, B, C, D ...) staggered in the direction of circulation of the gases and the materials, which are measured the average temperatures in each of the zones, which each temperature measured is compared to a reference temperature determined according to the operating conditions specific to the zone considered and which is produced locally in either zone, a lowering of the average temperature each time the measured temperature reaches the reference temperature there, to permanently maintain the average temperature in each zone below the corresponding reference temperature. 4. Treatment method according to claim 3, characterized in that the division of the installation into staggered zones (A, B, C, D, ....) is done so as to control the temperatures in at least one zone A at the base of reaction chamber 1 in the dense zone of the fluidized bed, zone B slightly above the limit level of this dense zone, zone C at the top of chamber 1 and zone D just upstream of the recovery device (2). 5. Treatment method according to one of the preceding claims,
characterized in that the local temperature reduction is carried out by injection into the area under consideration of a cold product in divided form. 6. Treatment method according to claim 5,
characterized by the fact that the cold product injected consists of sprayed water or steam. 7. Treatment method according to claim 5,
characterized in that the cold product injected consists of particles recovered at the outlet of the recovery device 2 and recycled in the fluidized bed after cooling. 8. Treatment method according to claim 5,
characterized by the fact that the cold product injected consists of part of the product gas, taken at the outlet of the recovery device 2 and recycled to the desired area after cooling. 9. Treatment method according to claim 5,
characterized by the fact that the cold product injected consists of at least part of the combustible material introduced into the upper part of the diluted zone 16 of the reaction chamber 1, with an adjustable flow rate, the largest particles falling into the dense zone 15 of the fluidized bed by crossing the diluted zone 16 and the finest particles being entrained with the fumes towards the recovery device 2 recycled in the fluidized bed 15. 10. Installation for processing combustible material comprising a vertical reaction chamber 1 provided with means 14 for supplying solid combustible material and, at its base, means 11 for fluidization by in jection of a gas with an adjustable flow rate and connected at its upper part, by a flue outlet pipe 12, to a device 2 for recovering entrained solid materials, comprising an upper outlet 21 and a lower outlet 22 for solid particles connected by a recycling circuit 23 at the base of the reaction chamber 1,
characterized by the fact that it comprises a means of localized cooling of the materials entrained with the fumes, placed upstream of the recovery device and a means of controlling the intensity of cooling as a function of the temperature of the materials accumulated in the device recovery, to keep it below a given reference temperature. 11. Treatment installation according to claim 10, characterized in that it comprises a plurality of zones (A, B, C, D, ...) of temperature control, staggered in the direction of circulation of gases and materials and each covering the entire cross section of the gas passage at the level in question, each control zone (A, B, C, D, etc.) being provided with means 31, 32, 33, 34 for measuring the average ambient temperature and a cooling means 61, 62, 63, 64 .... provoking, as for a localized reduction of this ambient temperature in the zone considered and that the means for measuring temperature 31, 34 and cooling 61 .. 64 of the control zones are associated with a regulation device comprising a set of comparators 41 of the temperatures measured with reference temperatures determined as a function of the desired operating conditions in each control zone A, B, C, D ... a set of regulating members 65 of the means d e cooling (61, 62, 63, 64 ...) and a means 7 for controlling the adjustment members 65 as a function of the differences observed between the measured temperatures and the reference temperatures. 12. Installation according to claim 11,
characterized in that the control zones (A, B, C, D, ...) are placed respectively, on the one hand at least at three levels of the combustion chamber, respectively at A in the dense part of the bed fluidized, in B at the boundary surface thereof and in C at the outlet of the combustion chamber, and on the other hand, in D in the separation device 2. 13. Treatment installation according to claim 11, characterized in that the localized cooling means consist, for each control zone (A, B, C, D,) of a member (61, 62, 63, 64 ) injection into the whole area of a product in divided form located at a temperature lower than the temperature measured in the control zone. 14. Treatment installation according to claims 10 and 11, characterized in that the cooling means comprise a member 27 for cooling the fumes leaving the separator 2 and a circuit 5 for sampling a portion of the fumes after cooling com ^p or - as many branches 6 opening respectively into the considered zone of the installation by means of an injector (61, 62, 63, 64) and each provided with an adjustment member (71, 72, 73, 74) of the reinjected flow, controlled by a regulating device 7 as a function of the temperatures obtained in the zone considered. 15. Treatment installation according to one of claims 11 to 14,
characterized by the fact that each control zone (A, B, C, D) covers the entire cross section of the gas passage at the considered location of the installation.

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