FR3012590A1 - METHOD FOR CONTROLLING A ROTATING FIRE CHAMBER (X) FOR THE COOKING OF CARBON BLOCKS - Google Patents

Abstract

A method of regulating a furnace (1) with chambers known as "fire (s) turning (s)" for cooking carbonaceous blocks (5), wherein the furnace comprises means (P3, P4, P5, P6, Pzpr) for determining, directly or indirectly, the heating pressure, in the heating zone (B), the method comprising a step of regulating the temperature (T1) for preheating to respect a set point while maintaining the suction flow rate (QO) within a predetermined range around a setpoint and while maintaining the heating pressure below a minimum threshold value.

Description

The present invention relates to ovens with chambers known as "fire (s) turning (s)", for the cooking of fire chambers (X) ROTATING (S) FOR COOKING CARBON BLOCKS. carbon blocks, more particularly anodes and carbon cathodes for the production by electrolysis of aluminum. More particularly, it relates to a method and a device for optimizing the control and safety of combustion in partition lines of such a chamber furnace.

Fire furnaces (x) turning (s) for cooking anodes are described in particular in the patent application WO201127042 to which reference will be made for more details about them. However, their structure and their operation are partially recalled, with reference to FIGS. 1, 2 and 3 below, respectively showing a schematic plan view of the structure of a furnace (x) rotating (s) and open chambers, with two lights in this example, for Figure 1, a partial perspective view and cutaway cross-section showing the internal structure of such an oven, for Figure 2 and a schematic view in longitudinal section along a span for Figure 3.

The baking oven (FAC) 1 comprises two casings or bays 1a and 1b parallel, extending along the longitudinal axis) (X along the length of the oven 1 and each having (e) a succession of transverse chambers 2 ( perpendicular to the axis) (X), separated from each other by transverse walls 3. Each chamber 2 is constituted, in its length, that is to say in the transverse direction of the furnace 1, by the juxtaposition, alternately, cells 4, open at their upper part, to enable the loading of the carbonaceous blocks to be cooked and the unloading of the cooled cooked blocks, and in which are stacked the carbonaceous blocks 5 to be embedded in a carbonaceous dust, and thin-walled hollow heating partitions 6, generally kept spaced by transverse spacers 6a The hollow partitions 6 of a chamber 2 are in the longitudinal extension (parallel to the major axis) (X of the oven 1) of the hollow partitions 6 of the other cha 2 members of the same bay 1a or 1b, and the hollow partitions 6 are in communication with each other by skylights 7 at the upper part of their longitudinal walls, facing longitudinal passages formed at this level in the walls transverse 3, so that the hollow partitions 6 form rows of longitudinal partitions, arranged parallel to the major axis) (X of the furnace and in which will circulate gaseous fluids (combustion air, fuel gas and gas and combustion fumes) allowing preheating and cooking the anodes 5, then cooling them. The hollow partitions 6 further include baffles 8, to elongate and distribute more uniformly the path of the combustion gases or fumes, and these hollow partitions 6 are provided at their upper part with openings 9, called "openings", closable by removable lids and formed in an oven crown block 1. The two bays 1a and 1b of the oven 1 are placed in communication at their longitudinal ends by turning flues 10, which make it possible to transfer the gaseous fluids of the oven. one end of each line of hollow partitions 6 of a bay 1a or 1b at the end of the line of corresponding hollow partitions 6 on the other bay 1b or 1a, so as to form substantially rectangular loops of lines of hollow partitions 6.

The principle of operation of rotating fire furnaces (x), also called "fire advance (x)" furnaces, consists in causing a flame front to move from one chamber 2 to another which is adjacent during a cycle, each chamber 2 successively undergoing stages of preheating, forced heating, fire, then cooling (natural then forced).

The firing of the anodes 5 is carried out by one or more lights or groups of lights (two groups of lights being represented in FIG. 1, in a position in which one extends, in this example, over thirteen chambers 2 of the span 1a and the other on thirteen chambers 2 of span 1b) which move cyclically from chamber 2 to chamber 2.

Each light or group of lights is composed of five successive zones A to E, which are, as represented in FIG. 1 for the light of the span 1b, arranged successively from the upstream downstream relative to the direction of flow of the gaseous fluids in the hollow partition lines 6, and in the opposite direction to the cyclic displacements from chamber to chamber: A) A preheating zone comprising, referring to the fire of the span 1a, and taking into account the direction of rotation of the lights indicated by the arrow at the flue flap 10 at the end of the oven 1 at the top in Figure 1: - a suction ramp 11 equipped, for each hollow partition 6 of the chamber 2 above of which this suction ramp extends, a system for measuring and regulating the flow of combustion gases and fumes by line of hollow partitions 6, this system can comprise, in each suction pipe 11 a which is secured to the suction ramp 11 and opening ns the latter, on the one hand, and, on the other hand, engaged in the opening 9 of one respectively of the hollow partitions 6 of this chamber 2, an adjustable shutter pivoted by a shutter actuator, for the flow control, and a flowmeter 12 measuring the flow rate QO fumes, slightly upstream, in the corresponding pipe 11a, a temperature sensor 13 for measuring the temperature TO of combustion fumes suction, and a pressure sensor (not shown) for measuring the suction pressure PO in the corresponding pipe 11 a, and - a preheating measuring ramp 15, substantially parallel to the suction ramp 11 upstream the latter, generally, above the same chamber 2, and equipped with temperature sensors (thermocouples) and pressure sensors for measuring the preheating static pressure P1 and the preheating temperature T1 prevailing in each of the partitions c 6 of this chamber 2 in order to be able to display and adjust this pressure P1 and this temperature T1 of the preheating zone; B) A heating zone comprising: - a plurality of identical heating ramps 16, two or, preferably, three, as shown in FIG. 1 and FIG. 3, or more depending on the cycle time; each equipped with burners or fuel injectors (liquid or gaseous) and temperature sensors (thermocouples), each of the ramps 16 extending above one of the chambers respectively of a corresponding number of adjacent chambers 2 , so that the injectors of each heating ramp 16 are engaged in the openings 9 of the hollow partitions 6 to inject the fuel therein; C) A natural blowing or cooling zone comprising: a so-called "zero point" ramp 17, extending above the chamber 2 immediately upstream of that below the most upstream heating ramp 16 , and equipped with pressure sensors for measuring the pressure in each of the hollow walls 6 of this chamber 2, in order to adjust this pressure, and - a blowing ramp 18, equipped with motor fans provided with a device for adjusting the ambient air flow blown into each of the hollow partitions 6 of a chamber 2 upstream of that located under the zero point ramp 17, so that the flow rates of ambient air blown into these hollow partitions 6 can be regulated by to obtain a desired pressure (slight overpressure or slight depression) at the zero point ramp 17; D) A forced cooling zone, which extends over three chambers 2 upstream of the blast ramp 18, and which comprises, in this example, two parallel cooling ramps 19, each equipped with motor fans and blow pipes injecting ambient air into the hollow partitions 6 of the corresponding chamber 2; and E) a working zone, extending upstream of the cooling ramps 19 and allowing charging and deflection of the anodes 5, and the maintenance of the chambers 2. Upstream of the heating ramps 16, the blowing ramp 18 and the forced cooling ramp (s) 19 comprise combustion air insufflation pipes supplied by motorcycle fans, these pipes being connected via the openings 9 to the hollow partitions 6 of the chambers 2 concerned. Downstream of the heating ramps 16, the suction ramp 11 is available for extracting the gases and combustion fumes, generally designated by the terms "combustion fumes", which circulate in the hollow partition lines 6. heating and cooking of the anodes 5 are provided both by the combustion of the fuel (gaseous or liquid) injected, in a controlled manner, by the heating ramps 16, and, to a substantially equal extent, by the combustion of volatile materials ( such as polycyclic aromatic hydrocarbons) of the pitch diffused by the anodes 5 into the cells 4 of the chambers 2 in zones of preheating and heating, these volatile materials, largely combustible, diffused into the cells 4 that can flow in the two partitions hollow 6 adjacent passages in these partitions, to ignite in these two partitions, thanks to residual combustion air present at this level, among the smoke es of combustion in the flue walls 6.

Thus, the flow of air and combustion fumes takes place along the lines of hollow partitions 6, and a negative pressure, imposed downstream of the heating zone B by the suction ramp 11 at the downstream end. of the preheating zone A, makes it possible to control the flow rate of the combustion fumes inside the hollow partitions 6, whereas the air coming from the cooling zones C and D, thanks to the cooling ramps 19 and especially to the ramp 18, is preheated in the hollow partitions 6, cooling the anodes 5 cooked in the adjacent cells 4, during its journey and serves as an oxidizer when it reaches the heating zone B. As and when the baking of the anodes 5 occurs, the whole of the ramps 11, 15, 17, 18 is cyclically advanced (for example every 24 hours or so) of a chamber 2, and the associated measurement and recording equipment and apparatus . For the heating ramps 16 and the cooling ramps 19, only the most upstream ramp is moved and placed in front of the others, each chamber 2 thus ensuring, successively, upstream of the preheating zone A, a loading function of the green carbonaceous blocks 5, then, in the preheating zone A, a natural preheating function by the fuel combustion fumes and pitch vapors leaving the cells 4 by penetrating the hollow partitions 6, given the depression in the hollow partitions 6 of the chambers 2 in the preheating zone A, then, in the heating or heating zone B, a heating function of the blocks 5 at about 1100 ° C., and finally, in the cooling zones C and D, a cooling function of the blocks baked 5 by the ambient air and, correspondingly, of preheating this air constituting the oxidant of the oven 1, the forced cooling zone D being followed, in the opposite direction to the direction of advance of the fire and flue gas circulation, an E zone for unloading the cooled carbonaceous blocks, then possibly for loading the green carbonaceous blocks into the cells. 4. The combustion fumes extracted from the fires by the ramps suction 11 are collected in a flue 20, for example a cylindrical duct partially shown in FIG. 2, with a flue flue 21 that can have a U-shaped shape (see dashed lines in FIG. turn of the furnace, and whose outlet 22 directs the combustion fumes sucked and collected to a smoke treatment center (CTF) not shown because not forming part of the invention. The FAC control method 1 essentially comprises temperature and / or pressure control of the preheating zones A, heating B and natural blowing or cooling C of the oven 1 as a function of predefined setpoint laws. The regulation of the FAC 1 takes into account a multitude of parameters in order to respect the balances of the thermal transfers in the partitions. Indeed, the firing of the carbonaceous blocks must respect in particular a curve of rise and fall in cooking temperature between the preheating zone and the working zone, so that the material undergoes the appropriate transformations and that finally the anodes obtained have the required mechanical and electrical characteristics. The pressure prevailing in the hollow partitions 6 must also remain, for each partition 6, substantially constant, or at least within a defined pressure range, throughout a cycle. The parameters to be considered are numerous, and a regulation regulation method of the FAC 1 must make it possible to influence one or the other of the parameters according to the measurements and to keep an optimal functioning of the FAC 1. FIG. schematically the organization of control of a FAC 1 according to the state of the art.

A central control unit 23 makes it possible to centralize all the data provided by the measurements, to account for the overall operation of the FAC 1. For example, the injectors of the heating ramps 16 are regulated as a function of the temperature in the partitions 6 of the heating zone B. More precisely, temperature sensors in the partitions 6 of the heating zone B make it possible to regulate in temperature each of the heating ramps 16, the fuel injection being regulated in particular so that the temperature in the partitions 6 in the heating zone B follows a predetermined temperature rise curve. In FIG. 3, the number of heating ramps 16 is three, the ramps being referenced HR1, HR2 and HR3 in FIG. 3, the temperature of the partition associated with each ramp being denoted respectively T4, T5 and T6. Each heating ramp 16 is associated with a controller 24 of the PID type, which are themselves connected to the central control unit 23. The controllers 24 recover the temperature measurements T4, T5 and T6 to regulate the injectors. In addition, the proportion of air / fuel must approach stoichiometric proportions as much as possible, to ensure combustion both with the fuel injected by the injection ramps and with the volatile materials diffused by the firing of the carbonaceous blocks. in the preheating zone A. The pressure prevailing in the partitions 6 of each chamber 2 of the FAC 1 must also respect a set point. For example, it is desirable to maintain, for each septum 6, a substantially constant pressure throughout a cooking cycle, or at least to maintain the pressure within a range of values. In particular, the speed of the fans of the blowing ramp 18 is adjusted as a function of a pressure value Pzpr measured in a partition 6 upstream of the heating ramps 16, and in particular measured by the zero point ramp 17. The shutter of FIG. the suction ramp 11 is regulated according to a temperature T1 and / or a preheating pressure P1 measured in a partition 6 of the preheating zone A. The preheating temperature T1 in a partition 6 of the zone In particular, preheating A is monitored. The temperature in the preheating zone A must allow the removal of the volatile matter contained in the pitch of the carbonaceous blocks. The resulting gases or vapors must then be sucked into the hollow partitions 6 and be burned immediately in the presence of oxygen in the combustion fumes arriving from the heating zone B. In fact, these gases or vapors may foul the equipment. , and in particular the suction pipes 11a and the pipes which lead to the smoke treatment center. Deposits can ignite and damage equipment. The preheating measurement ramp 15 then makes it possible to obtain information on the preheating temperature T1 prevailing in a partition 6 upstream of the suction ramp 11 and downstream of the heating ramps 16, in the preheating zone A, and monitor the cooking. When the preheating temperature T1 thus measured deviates from too much of a set point, interventions must be made on the FAC 1 to bring the temperature T1 measured by the preheating measurement ramp 15 to an acceptable value. However, the interventions must not change the air flow in the partitions 6 too much, because then baking blocks is no longer respected. Thus, the preheating temperature T1 measured by the preheating measurement ramp 15 is in fact regulated while maintaining the preheating pressure P1 measured by said preheating measurement ramp 15 in a predetermined pressure range, around a value of setpoint. For this purpose, the preheating measurement ramp 15 and the suction ramp 11 are connected to the same controller 25 of the PID (Proportional Integral Derivative) type, itself also connected to the central control unit 23. The opening of the shutter of the suction ramp 11 can thus be regulated according to the measurement of the pressure P1 and the preheating temperature T1 by the controller 25. The regulation of the preheating temperature T1 in a pressure range Preheating P1 does not provide complete satisfaction. Indeed, the preheating pressure P1, which is in general a vacuum, measured by the preheating measurement ramp 11 is a static measurement, so that it does not make it possible to account for a change in the flow rate of the flow. fumes circulating in partitions 6 of the FAC 1. For example, a problem often encountered in a FAC 1 is the clogging of the partitions 6. Indeed, when a partition 6 is clogged, even partially, the flow of fumes is hindered. The plugging phenomenon can have several origins, in particular the accumulation of carbonaceous dust originating from the firing of the carbonaceous blocks in the cells 4 and passing through the walls of the partitions, the debris coming clogged the partitions 6 or the deformation of the partitions 6 disturbing the flow of fumes.

Clogging can have several undesirable effects. First, the cooking temperature curve is no longer respected. Above all, the heating ramps 16 continuing to inject fuel into the partitions 6 and the blowing ramp 18 continuing to blow combustion air, the accumulation of volatile fuel material upstream of the plug can reach a dangerous level, and to the extreme produce an explosion in the oven. The phenomenon of clogging is therefore even more dangerous when it occurs downstream of the heating ramp 16, after the fuel injection. It is therefore important to monitor the clogging phenomenon downstream of the heating ramp 16.

However, when a partition 6 of a chamber 2 upstream of the preheating measurement ramp 11 is plugged, the preheating pressure P1 does not vary. Thus, a malfunction of the FAC 1 may not be visible by the measurement of the preheating pressure P1. The regulation of the preheating temperature T1 is distorted.

It is known to use the flowmeter 12 on the suction ramp 11 to measure the suction flow rate QO. The measurement of a flow provides more information than the measurement of a pressure, since the flow rate accounts for the dynamic phenomena, the circulation of the fluids in the partitions 6. However, the suction flow rate QO is generally used. only as an index. Indeed, there are parasitic phenomena that can occur in the FAC 1, which distort the flow measurements. The suction flow rate QO is therefore not a reliable indicator. In particular, on each span 1a, 1b, depending on the stage of the cooking cycle, chambers 2, located downstream of the chambers 2 of the preheating zone A, are not used. The partitions 6 'of these rooms are said to be dead because they normally have no influence on the cooking in progress. However, dead walls can be a source of infiltrations of parasitic air, said rear air, due to leaks. The rear air passes through the dead partitions 6 'and reaches the suction ramp 11.

In addition, the walls of the partitions 6 are porous, so that in the preheating zone A in particular, where the static vacuum is normally the most important, air coming from outside can infiltrate through the walls of the walls. partitions 6. The amount of air infiltrated through the porous walls is all the more important as static depression is important.

Thus, parasitic phenomena can mask a drop in flue gas flow due to clogging, and prevent the implementation of the necessary operations to remedy it. A problem underlying the invention is therefore the determination of the origin of the air circulating in the partitions 6, at the base of the pressure, temperature and flow measurements, in order to regulate the operation of the FAC 1. There is therefore a need to develop a method of regulating the FAC 1 to make reliable measurements to account for the operation of the FAC 1, without disturbing the operation of the furnace, nor involve additional costs.

In particular, there is a need to develop a method for regulating the FAC to identify the origin of the flow passing through the suction ramp, in particular to account for infiltrations of stray air during capping and rear air inlets through the dead partitions. For this purpose, according to a first aspect, there is provided a control method of a chamber furnace said "fire (x) turning (s)" for cooking carbon blocks.

The furnace comprises a succession of chambers extending in a preheating zone, a heating zone and a natural cooling zone, the chambers being arranged in series along the longitudinal axis of the furnace. Each chamber is constituted by the juxtaposition, transversely to said longitudinal axis and alternately, cells in which are arranged carbon blocks to cook and hollow heating partitions, the partitions of a chamber being in communication and aligned with the partitions of the other chambers, parallel to the longitudinal axis of the furnace, in partition lines in which cooling and oxidizing air circulates and combustion gases. A suction ramp is connected to each of the partitions of the first chamber of the preheating zone by one respectively suction pipes. The necessary combustion air is partly injected by a discharge ramp of the natural cooling zone, connected to at least one fan, and partly infiltrated by depression through the partition lines. The fuel required for cooking the carbonaceous blocks is in turn partially injected by at least one heating ramp each extending over one respectively of at least two adjacent chambers of the heating zone, and capable of injecting in each of the partitions of the corresponding respective chamber of the heating zone.

The oven further comprises at least one temperature sensor for measuring a preheat temperature in the partition of a chamber of the preheating zone, between the suction ramp and the heating ramp and comprises a flow meter for measuring a flow rate of suction of the air and fumes passing in at least one suction pipe.

The oven further comprises means for determining, directly or indirectly, the heating pressure, in the heating zone, the preheating temperature is regulated to meet a set point while maintaining the suction flow in a predetermined range around a set value and while keeping the heating pressure below a minimum value. According to an exemplary embodiment, the oven further comprises at least one temperature sensor for measuring the suction temperature of the air in at least one suction pipe, and in which the suction flow rate measured in the same pipe suction is a flow rate regulated by the suction temperature. The means for directly determining the pressure in a partition of the heating zone include, for example, a heating pressure sensor placed on the at least one heating ramp for measuring the pressure in a partition of the heating zone. Alternatively, the means for indirectly determining the pressure in a partition of the heating zone comprises a pressure sensor for measuring the pressure in the chamber wall immediately downstream of the heating zone and a pressure sensor for measuring the pressure. in the partition of the chamber immediately upstream of the heating zone. Preferably, the flowmeter for measuring the suction flow rate measures the flow of air and fumes passing through a sill in the suction pipe in question. When the heating pressure exceeds the minimum threshold value, an operation to unclog one or more partitions (6) is advantageously implemented. Any other operation depending on the oven state determined by the new process may also be undertaken In a second aspect, there is provided a so-called "rotating fire" chamber furnace for baking blocks. The furnace is as previously described, and is particularly suitable for the above-mentioned process to be used therein, In particular, the furnace comprises means for directly determining the heating pressure in the heating zone comprising at least a heating pressure sensor placed on the at least one heating ramp for measuring the pressure in a partition of the heating zone, the preheating temperature sensor can then be connected to the suction ramp, so that the oven is devoid of ramps dedicated exclusively to measurements 30 Other features and advantages will become apparent in the light of the description given below without limitation an example of embodiment described with reference to Figure 4 attached, which is a schematic longitudinal sectional view along a span of a FAC 1. The claimed method of detection is implemented on a furnace 1 as shown in Figures 1 and 2, and described in introduction, using a control system such as that shown schematically in Figure 4. The method is to use the measurement of the suction flow rate QO on the ramp suction 11 for regulating the preheating temperature T1 measured in a partition 6 of the preheating zone A: the preheating temperature T1 is regulated in a flow range QO.

In fact, the measurement of the suction flow rate QO is more reliable than the measurement of the preheating pressure P1 on the preheating measurement ramp 15 according to the state of the art because the preheating measurement ramp 15 measures a static depression. , Thus, the preheating pressure P1 measured by the preheating measurement ramp 15 does not vary or very little, when a partition is clogged. On the other hand, measurement of the OO flow rate accounts for a change in the flue gas flow in the event of clogging, provided that the origin of the measured flow is determined, and in particular to distinguish the spurious air inlets from the flow of 20 combustion fumes. Thus, the method according to the claims proposes to further use the determination of the value of the heating pressure, in a partition 6 of a chamber 2 of the heating zone B, to deduce the state of operation of the oven. The heating pressure can be determined directly or indirectly. For example, the heating pressure is directly measured on at least one heating ramp 16, a pressure sensor being placed closer to an injector of the heating ramp 16 in question to measure a pressure P4. The pressure sensor can be inserted into the quarney directly upstream of the quarl through which the injector of the heating ramp 16 injects the fuel into the partition 6. The determination in a direct way thus makes it possible to eliminate the measurement ramp Thus, even by adding pressure sensors to the heating ramps 16, the removal of the zero point ramp 17 allows substantial material savings. Alternatively, the heating pressure can be determined indirectly, by means of a pressure measurement immediately upstream of the heating zone B and by a pressure measurement immediately downstream of the heating zone B. For example, the ramp of zero point 17 provides a measurement of the vacuum Pzpr in a partition 6 of the chamber 2 immediately upstream of the heating zone B and a pressure sensor placed in a partition 6 of the chamber 2 of the preheating zone B immediately in downstream of the heating zone B provides a measure of the P3 depression. A correlation between these two measurements makes it possible to deduce a heating pressure therefrom. The value of the heating pressure can be positive, or negative. In the latter case, it is called heating depression. Thus, whether directly or indirectly, the value of the heating pressure is known. As indicated in the introduction, the FAC 1 is regulated in particular by taking into account the preheating temperature T1 measured by the preheating measurement ramp 15 in a partition 6 of the preheating zone A. The flow rate QO measured by the flowmeter 12 characterizes the flow of air and smoke 25 which passes through the suction pipe 11 a. The air and the measured fumes have three origins: - the rear air infiltrating through the dead partitions, the parasitic air infiltrating through the partitions 6 in the preheating zone A, the fumes coming from the heating zone B. Taking into account the value of the heating pressure in the heating zone B makes it possible to report reliably on the state of the oven.

Indeed, the depression in the heating zone B is smaller than in the preheating zone A, so that the infiltrations of air by the partitions 6 in the heating zone B can be considered negligible. However, the pressure in the heating zone B must be as low as possible to ensure suction and flue gas circulation. Thus, from the moment when the pressure in the heating zone is greater than a set value, there is a strong indicator of the presence of a plug in a partition 6. Thus, it is possible from a variation of the value of the pressure in the heating zone to deduce the state of the furnace. Thanks to the correlation between the flow rate QO and the depression in the heating zone B, it is deduced the state of the FAC 1, and in particular if a partition 6 is plugged. Measurements can be implemented to regulate the preheating temperature T1 accordingly. Additional indicators may be used as supplements to provide clues as to the state of the oven. These indicators can serve as a clue as to a malfunction, but do not allow to determine the origin of the dysfunction. For example, the value of the temperature TO in the suction pipe 11 may be used as indicating that the cooking is not proceeding as intended.

Thus, a decrease in the temperature TO may indicate that cooler air coming from the dead bulkheads reaches the suction pipe 11a. However, the temperature TO also drops when a partition 6 is plugged and the hot air coming from the heating zone B does not completely reach the preheating zone A.

In nominal operation, that is to say without stray air inlets or by dead partitions, or by infiltrations, the measured preheating temperature T1 is maintained, at a given instant of the cycle, at a predetermined value, with possibly a tolerance interval. The measurement of the flow rate QO and the determination of the pressure in the heating zone B provide nominal values. When rear air reaches the suction pipe 11a, the preheating temperature T1 is decreased if the system maintains the same flow rate QO.

The intake of rear air arriving at the suction pipe 11 has resulted in an increase in the suction flow rate QO. Considering the P4 depression in the heating zone B, an operator can make sure that the flow variation is not due to a plugged partition. The range of values allowed for the suction flow rate QO can then be modified to take account of this rear air supply and maintain the preheating temperature T1 at its nominal value. In addition, operations can be undertaken to adjust the sealing defects of the dead partitions. When a partition is clogged, the temperature T1 in the preheating zone A decreases, due to the lack of smoke in the heating zone B. Increase the power of the injectors in the hope of increasing the temperature T1 is not effective , because of the plug, in addition to being dangerous, because increasing the risk of explosion, and not respecting the temperature curve in the heating zone B. The QO flow can be increased by respecting a range determined. Thus, even by increasing the range of allowed values for the QO flow rate, the temperature T1 does not reach the target determined value. Considering the depression P4 in the heating zone B, the operator can see an increase in the heating pressure P4, indicating that the smoke does not circulate properly due to the presence of a plug. Operations can then be undertaken to remove the cap. The measurement of the pressure P1 by the preheating measurement ramp 15 becomes superfluous. Thus, by returning the thermocouple measuring the preheating temperature T1 to the suction ramp 11, the preheating measurement ramp 15 can be suppressed. By using the suction flow rate QO and the pressure of the heating zone B to regulate the FAC 1, the risks associated with capping are reduced. The security of FAC 1 is increased. Figure 4, illustrating an embodiment of a FAC 1 implementing the control method described above will now be described in more detail. The same references as those of FIG. 3 designate the same elements.

The FAC 1 of FIG. 4 comprises two levels of control for regulating the different parameters of the FAC 1. A first level control unit 26 is connected to the suction ramp 11, and records the measurements of the flow rate OO, the pressure PO and suction temperature TO in at least one suction pipe 11a. In practice, each suction pipe of the suction ramp 11 is provided with means for measuring the flow, the pressure and the temperature in the pipe in question. The preheating measurement ramp of the state of the art is suppressed. A thermocouple 27, measuring the preheating temperature T1 in the partition 6 of the chamber 2 above which the suction ramp 11 extends, is connected to the suction ramp 11. According to an embodiment of the FAC 1, the flow in each pipe 11a suction is controlled through a sieve placed in the suction pipe 11a. The leaf comprises a plurality of flaps, pivoting on their axes, and exerting control on the suction flow QO. The suction flow rate QO in each suction pipe 11 a is then preferably measured directly at the level of the sill so that it is ensured that the measured flow rate QO is that actually passing through the adjustable shutter. Since the pressure losses of the leaf are known, the suction flow rate QO is measured with an increased accuracy compared to a measurement elsewhere in the suction pipe 11a. In addition, the size in the suction pipe 11 has been reduced. In practice, and as illustrated in FIG. 4, each of the three heating ramps 6 comprises two injectors per partition 6 and a pressure sensor, placed upstream of the injector the most upstream of the heating ramp 16. It is thus obtained three heating pressure measurements P4, P5 and P6, each associated with a heating ramp 16 for determining the value of the heating pressure. Measurement by the sensors can be synchronized with the injection so as not to damage the sensors if necessary.

The heating pressure considered can then be the average of the three measurements P4, P5 and P6 or only one of the measurements, for example the one deviating the most from the reference value, can be taken into account.

The first level control unit 26 is furthermore connected to the means for determining the depression in the heating zone B. According to the illustrated example, the first level control unit 26 is connected to associated pressure sensors. each injector, so as to collect the measurements of the depressions P4, P5 and P6 in the partitions 6 of the heating zone B. The first level control unit 26 makes it possible to analyze the measurements collected and to act on the suction ramp 11 to regulate the opening of the shutter. Preferably, the first level control unit 26 corrects the measurement of the flow rate QO by the temperature TO and the depression PO measured in the suction pipe 11a. Indeed, the flowmeter 12 used is calibrated to give a measurement of the flow rate QO under normal conditions of pressure and temperature. However, in the suction pipe 11a, the temperature and pressure can vary greatly, and in any case do not correspond to these normal conditions. Taking into account the temperature TO and / or the suction pressure PO, it is possible to correct the measurement of the suction flow rate QO and to obtain reliable values. The first level control unit 26 is connected to a second level control unit 28, which centralizes the data of the entire oven and makes decisions on oven control. For example, the second level control unit 28 is connected to a controller 24 of each injector. The second level control unit 28 performs the calculations based on the parameters collected, and transmits the commands to the injectors controllers 24, in order to regulate the parameters of the injectors, and in particular the order of the injections by the injectors, the time of the injectors. injection and injection power. The zero point ramp 17 of the state of the art is also deleted. The flow of ambient air blown into each of the hollow partitions 6 by the motor-fans of the blower ramp 18 is then regulated taking into account the vacuum measurements in the heating zone B, and in particular the depression P6 in the partitions 6 the most upstream of the heating zone B.

As an indication, Table 1 below gives examples of numerical values for the predetermined range of values authorized for the suction flow rate QO and for the heating pressures P4, P5, P6 associated with the heating ramps 16, such as expected throughout a cycle. It is also indicated in Table 1, for the temperatures T4, T5, T6 measured respectively under one of the heating ramps 16 of the FAC 1, the beginning of cycle and end of cycle values corresponding to those expected in the context of nominal operation of the FAC 1. Table 1 is carried out in the case where, during a baking cycle, the preheating temperature T1 varies from 350 ° C. to the cycle flow rate at 900 ° C. at the end of the cycle. The numerical values depend in practice on the cycle time, the anodes and the characteristics of the FAC 1. Suction flow QO 1400 to 2900 Nm3 / h Pressure P6 from -20 Pa to +20 Pa Pressure P5 from -40 Pa to 0 Pa Pressure P4 from -60 Pa to -20 Pa Temperature T6 from 750 ° C to 1150 ° C Temperature T5 from 950 ° C to 1220 ° C Temperature T4 from 1000 ° C to 1220 ° C Table 1 15 (NB: flow rate in Nm3 / h corresponds to the measurement of the normalized QO flow, that is to say with correction by the temperature TO and the suction pressure PO). Table 2 below gives examples of values, at a given time, for the temperature TO in a suction pipe 11a considered, for the temperature T1 in a partition of the preheating zone A, for the depression PO in the suction pipe 11a considered, for the pressure P4 in a partition 6 of the heating zone B and for the flow rate QO in the suction pipe lla considered, according to three modes of operation : - nominal: the operation of the oven is nominal, - rear air: air infiltrated by the dead partitions reaches the suction pipe 11a, - plug: at least one partition 6 is at least partially clogged. Nominal Rear Air Plug T1 (° C) 750 750 650 TO (° C) 400 300 300 PO (Pa) -200 -400 -400 P4 (Pa) -40 -40 -10 QO (Nm3 / h) 1500 2000 2000 Table 2 Table 2 thus illustrates that when rear air infiltrations occur, the preheating temperature T1 does not vary, because the rear air does not reach this portion of the oven. However, the back air reaches the suction pipe, so that the TO temperature and the PO pressure in the suction pipe fall. The flow rate QO in the suction pipe may be augered to draw in the rear air and continue to maintain the required flow rate in the oven to maintain the temperature T1 preheating. When a plug is formed in a partition 6 of the oven, the preheating temperature T1 decreases. The temperature TO in the suction pipe also decreases. Even by increasing the flow rate up to the maximum value allowed at the given moment, the preheating temperature T1 does not return to its nominal value. The pressure P4 in the heating zone, however, has increased, leaving the range of authorized values indicated in Table 1, and thus indicating the presence of a plug.

The connection between the different equipment and the means of control of the FAC 1 can be carried out by means of a wired network and / or of the Wi-Fi type. Thanks to the new control method, the security of the FAC 1 is reinforced, because it allows to detect more reliably than in the state of the art risk dysfunctions, including plugs in the partitions.

In addition, the new method simplifies the furnace, by eliminating the preheating measurement ramp 11 and the zero point ramp 17 of the furnaces of the state of the art. Thus, the furnace 1 can advantageously be devoid of any ramp exclusively dedicated to measurements, as are the preheating measurement ramp 11 and the zero point measurement ramp 17.

Claims (7)

REVENDICATIONS1. Method for regulating a furnace (1) with so-called "rotating (s)" chambers for cooking carbonaceous blocks (5), said furnace (1) comprising a succession of chambers (2) extending in a preheating zone (A), a heating zone (B) and a natural cooling zone (C), the chambers (2) being arranged in series along the longitudinal axis (XX) of the oven (1), each chamber (2) being constituted by the juxtaposition, transversely to said longitudinal axis (XX) and alternately, of cells (4) in which are arranged carbon blocks (5) to be cooked and hollow partitions (6), the partitions ( 6) of a chamber (2) being in communication and aligned with the partitions (6) of the other chambers (2), parallel to the longitudinal axis (XX) of the furnace (1), in lines of partitions (6) in which circulate cooling air and combustion and combustion gases, a suction ramp (11) being connected to each of the partitions (6) of a first chamber re (2) of the preheating zone (A) by one respectively suction pipes (11a), the necessary combustion air being partially injected by a blowing ramp (18) of the natural cooling zone ( C), connected to at least one fan, and partially infiltrated by depression through the partition lines (6), and the fuel necessary for cooking the carbonaceous blocks (5) being partially injected by at least one ramp (16). ) each extending over one respectively of at least two adjacent chambers (2) of the heating zone, and adapted to inject fuel into each of the partitions (6) of the corresponding respective chamber (2) of the heating zone (B), said oven further comprising at least one temperature sensor for measuring a preheating temperature (T1) in the partition (6) of a chamber (2) between the suction ramp (11) and the heating ramps (16) and a flow meter (12) for measuring a suction flow rate (QO) air and fumes passing through at least one suction pipe (11a), the method being characterized in that the furnace further comprises means (P3, P4, P5, P6, Pzpr) for determining , directly or indirectly, the heating pressure, in the heating zone (B), the method comprising a step of regulating the temperature (T1) preheating to meet a set point while maintaining the suction flow (QO) in a predetermined range around a setpoint and while maintaining the heating pressure below a minimum threshold value. 2. A method of regulation according to claim 1, wherein the oven (1) further comprises at least one temperature sensor for measuring the suction temperature (TO) of the air in at least one pipe (11a) of suction, and wherein the suction flow rate (QO) measured in the same suction pipe (11a) is a flow rate standardized by the suction temperature (TO). 3. Control method according to claim 1 or claim 2, wherein the means for determining, directly or indirectly, the pressure in a partition (6) of the heating zone (B) comprises a heating pressure sensor (P4 , P5, P6) placed on the at least one heating ramp (16) for measuring the pressure in a partition (6) of the heating zone (B), the pressure in the heating zone (B) then being determined directly . 4. Control method according to claim 1 or claim 2, wherein the means for determining, directly or indirectly, the pressure in a partition (6) of the heating zone (B) comprises a pressure sensor for measuring the pressure. (P3) in the partition (6) of the chamber (2) immediately downstream of the heating zone (B) and a pressure sensor for measuring the pressure (Pzpr) in the partition (6) of the chamber (2) immediately upstream of heating zone (B). 5. Control method according to one of the preceding claims, wherein the flow meter (12) for measuring the suction flow (QO) measures the flow of air and fumes passing through a gate in the suction pipe ( 11a) considered. 6. Control method according to any one of the preceding claims, wherein, when the heating pressure exceeds the minimum threshold value, an operation to unclog one or more partitions (6) is implemented. 7. Furnace (1) with chambers said "fire (s) turning (s)" for cooking carbonaceous blocks (5), specially designed for the implementation of the method according to one of the preceding claims, the oven ( 1) being characterized in that it comprises means (P4, P5, P6) for directly determining the heating pressure in the heating zone (B) which comprise at least one heating pressure sensor (P4, P5, P6) placed on the at least one heating ramp (16) for measuring the pressure in a partition (6) of the heating zone (B) and in that a preheating temperature sensor (T1) is connected to the suction ramp (11), so that the oven (1) is devoid of 10 ramps dedicated exclusively to measurements.