EP1412689B1 - Method and cooling device for the subracks in a chamber furnace - Google Patents

Description

Field of the invention

The invention relates to the field of so-called "ring furnace" furnaces for firing carbonaceous blocks, including open-type chamber furnaces. The invention concocie more particularly a method and a device for cooling the cells of such ovens before maintenance and maintenance operations.

State of the art

Open chamber type open fire furnaces are well known per se and described in particular in patent applications FR 2,600,152 (corresponding to US Pat. No. 4,859,175) and FR 2,535,834 (corresponding to the British application). GB 2 129 918).

A revolving furnace comprises a succession of aligned chambers, each chamber comprising a plurality of elongate cells separated by hollow heating partitions.

A firing cycle of carbonaceous blocks, for a given chamber, typically comprises the charging of the cells of this chamber with green carbonaceous blocks, the heating of this chamber up to the firing temperature of the carbonaceous blocks (typically from 1100 to 1200.degree. ), cooling the chamber to a temperature that allows removal of the burned carbonaceous blocks and cooling of the chamber to room temperature. The principle of the rotating light is to successively carry out the heating cycle on the furnace chambers by a displacement of the heating means (such as burner ramps) and suction means.

Thus, a given chamber passes successively by periods of preheating, cooking and cooling. Typically, a dozen rooms are "active" simultaneously: four in a so-called cooling zone, three in a so-called heating zone, and three in a so-called preheating zone. Active rooms are what is called a "fire".

However, the cooling times of the cells after removal of the carbon blocks, which are very long, limit the productivity of the furnaces when interventions are required on the furnace, including the replacement of partitions, because it is not possible for health reasons, to involve operators inside the cells before the wall temperature is less than about 30 ° C, which requires waiting times generally greater than 3 days.

The Applicant has therefore sought simple and industrializable means to accelerate the cooling of the cells.

Description of the invention

The subject of the invention is a method for cooling a rotating furnace furnace, characterized in that it comprises producing a flow F of cooling fluid inside the cell and that at least a portion Fr of said stream F flows substantially vertically along determined surfaces of the walls of the cell.

• au moins un premier moyen apte à produire un flux F de fluide de refroidissement à l'intérieur de l'alvéole, tel qu'un moyen de ventilation ;
• au moins un deuxième moyen apte à provoquer un écoulement sensiblement vertical d'au moins une partie Fr dudit flux F le long de surfaces déterminées des parois de l'alvéole, tel qu'un moyen de confinement.

The subject of the invention is also a device for cooling a rotating furnace furnace, characterized in that it comprises:

• at least one first means capable of producing a flow F of cooling fluid inside the cell, such as a ventilation means;
• at least one second means capable of causing a substantially vertical flow of at least a portion Fr of said stream F along determined surfaces of the walls of the cell, such as a confinement means.

The invention also relates to a method of cooling a rotating furnace furnace using the device of the invention.

The Applicant has found that the substantially vertical flow of the coolant flow near the walls of the cell allowed to considerably accelerate the rate of cooling of the latter. The invention may thus allow, in certain cases, to eliminate a chamber by fire in an industrial size oven.

The invention will be better understood with the aid of the figures and the detailed description which follows.

Figure 1 illustrates a perspective view, partially exploded, of a rotating furnace.

Figure 2 illustrates, seen from above (Z axis), a span of furnace with rotating light.

FIG. 3 illustrates an embodiment of the device of the invention, in the standby position, (a) seen from the narrow side (X axis) and (b) seen from the wide side (Y axis).

FIG. 4 illustrates an embodiment of the device of the invention, in the deployed position, (a) seen from the narrow side (X axis) and (b) seen from the wide side (Y axis).

Figures 5 and 6 illustrate the movement of the cooling fluid flow obtained with the preferred embodiment of the device of the invention.

As illustrated in Figures 1 and 2, a rotating furnace comprises a succession of chambers (10, 11, 12, ...) arranged in series. Each chamber comprises an alternation, in the transverse direction (Y axis), elongate cells (2) and hollow heating partitions (3) arranged in the longitudinal direction (X axis). As an illustration, the dotted line (1) of Figure 1 delimits one of the chambers and shows that it comprises several cells (2) arranged in parallel and separated by partitions (3).

The cells (2) are delimited by heating partitions (3), transverse wall pillars (4) and a floor (24). The heating partitions (3) and the transverse wall pillars (4) form substantially vertical walls (2A, 2B); the floor (24) forms a substantially horizontal bottom (2C). The ends of the heating partitions (3) generally comprise transverse walls (5) provided with openings (6). The heating partitions (3) comprise thin side walls (9) generally separated by spacers (7) and baffles (8). The heating partitions (3) are provided with access means (20) called "openers" which serve in particular to introduce heating means (such as burner injectors) (not shown) or suction means (21, 22). The elements (2, 3, 4, 5, 24) of the furnace are formed of refractory materials, typically using refractory bricks. Each cell (2) typically has a depth of 5 m.

FIG. 1 shows a typical stack of carbonaceous blocks (31) in a cell (2), with a coating powder (32), during a cooking operation thereof.

The rooms form a long span in the direction C of the fire. A rotating furnace typically comprises two parallel spans, each having a length of the order of one hundred meters. The spans are generally delimited by lateral walls (23).

During the firing operations, a gas flow consisting of air, heating gas, vapors released by the carbonaceous blocks or combustion gases (or, most often, a mixture thereof) flows, in the long direction of the furnace (X axis), in a succession of hollow heating partitions (3) which communicate with each other. This gas stream is blown upstream of the active chambers and is sucked downstream thereof. The heat produced by the combustion of the gases is transmitted to the carbonaceous blocks (31) contained in the cells (2), which causes their cooking.

Detailed description of the invention

According to the invention, the method of cooling a furnace (2) of a rotating furnace, said recess (2) comprising walls (2A, 2B), is characterized in that it comprises the production of a flow F of cooling fluid inside the cell (2) and that at least a portion Fr of said flow F flows substantially vertically along predetermined surfaces of the walls (2A, 2B) of the cell (2).

The inside of the cell corresponds to the space normally occupied by the carbonaceous blocks (31) and the coating powder or "dust" (32) during cooking.

A substantially vertical flow means a flow for which the vertical component of the gas flow F is significantly larger than the horizontal components (typically about ten times greater), so as to maximize the flow of thermal energy extracted from walls and evacuated outside the cell. Said flow is preferably not very turbulent, and more preferably substantially laminar. Said vertical flow can be ascending or descending.

Said flow F is typically a forced flow, which is produced for example by blowing or suction cooling fluid.

Said portion Fr of said stream F typically circulates in a so-called "flow" section S near the walls of the cell, with a rapid flow of said fluid in a direction substantially parallel to said walls. The flow Fr circulates preferably in a restricted volume V, close to said walls, which makes it possible to obtain efficient evacuation of the heat from the walls for acceptable fluid flow rates (typically between 1 and 10 Nm ³ / s).

Said flux F typically comprises two main components, namely said part Fr, which "licks" the walls of the cell, and a part Fo, which introduces the fluid cooling in the cell. In the preferred embodiment of the invention, the flows Fr and Fo are substantially parallel and flow in opposite directions, as shown in FIG. 6. The flow rates of Fr and Fo are typically substantially identical.

The cooling fluid is preferably a gas, or a mixture of gases. It is advantageous to use air in order to limit operating costs, that is to say that said fluid contains air. The cooling fluid is advantageously moist, that is to say it contains water (typically in the form of steam or fine gullets), so as to increase its specific heat capacity. The moisture content of the fluid can be adjusted, for example as a function of the temperature of the walls of the cell. In a preferred variant of the invention, said fluid comprises a mixture of air and moisture. Typically, the fluid that is injected into the cell is air at room temperature more or less loaded with moisture.

The flow of cooling fluid can be in open circuit, in that it is discharged into the ambient atmosphere after absorbing part of the heat of the walls of a cell during its flow inside the cell. this.

• au moins un premier moyen (101) apte à produire un flux F de fluide de refroidissement à l'intérieur de l'alvéole (2) ;
• au moins un deuxième moyen (103) apte à provoquer un écoulement sensiblement vertical d'au moins une partie Fr dudit flux F le long de surfaces déterminées des parois (2A, 2B) de l'alvéole (2).

According to the invention, the cooling device (100) of a rotating furnace furnace (2), said recess (2) comprising walls (2A, 2B) and a bottom (2C), is characterized in that 'He understands :

• at least one first means (101) capable of producing a flow F of cooling fluid inside the cell (2);
• at least one second means (103) capable of causing a substantially vertical flow of at least a portion Fr of said stream F along determined surfaces of the walls (2A, 2B) of the cell (2).

Said first means (101) is typically a ventilation means, such as a suction or blowing means.

Said second means (103) is advantageously a so-called "confinement" means capable of reducing the flow section S of said flow F close to the walls of the cell, so as to cause a rapid flow of said fluid in a substantially parallel direction to the said walls. The flow F then circulates in a restricted volume V near said walls.

The flow section S is approximately equal to L x P, where L is the confinement width and P is the average internal perimeter of the cell. The width L is preferably between 5 cm and 25 cm, and more preferably between 10 cm and 20 cm. Width too low leads to significant pressure drops. Width too large leads to a flow rate too low, and therefore insufficient cooling speed.

Preferably, the confinement of said flow F also causes an increase in the flow velocity Ve of said fluid. The flow rate of the cooling fluid in said portion Fr of said stream F is advantageously between 2 and 20 m / s. Too low a speed does not reduce interestingly the cooling time of a cell. On the other hand, a very high flow rate requires expensive ventilation means and high energy consumption. The fluid flow rate of said flow is typically between 1 and 10 Nm ³ / s for industrial furnaces.

The containment means (103) is typically a conduit, such as a rigid or flexible conduit or a flexible skirt, a first end of which is connected to said (or each said) ventilation means (101) and a second end thereof (104) can be placed inside the cell (2). In this case, the cooling fluid, which is set in motion by means (or means) of ventilation (101), is guided by the conduit and injected into the cell (or sucked from it). ci) by at least one opening at said second end (104). The conduit restricts the flow area S of said flow by forcing said flow to flow between the surface of said conduit and said walls (2A, 2B).

The containment means (103) is advantageously removable and / or retractable, so as to facilitate the establishment of the device. For example, the containment means (103) may be a detachable rigid conduit (i.e., a conduit that can be detached from the device (100)) which can be put into place in the cell and then connected to the ventilation means (101) of said device.

The containment means (103) can be connected to the ventilation means (101) by means of a connecting means (102).

In a preferred embodiment of the invention, the containment means (103) is a retractable tubular conduit having at least one retracted position (as shown in FIG. 3) and at least one deployed position (as illustrated in Figure 4). The length of said duct can then be variable or adjustable. This embodiment has the advantage of allowing easy implementation of the device.

As illustrated in FIGS. 3 and 4, the retractable tubular duct may be in the form of a bellows (typically when the section is substantially circular or ovoid) or of accordion (typically when the section is substantially rectangular or square), which facilitates its deployment. Said duct may also have other structures, such as a telescopic structure formed of several duct sections slidably inserted into one another. The conduit (103) may be retracted or deployed using the deployment means (106, 107), such as a motor and cables.

The duct (103) is preferably such that it can be deployed to a short distance D from the bottom (2C) of the cell, said distance D being preferably less than about 50 cm. The distance D is typically of the order of 20 cm.

The duct dimensions are preferably such that the average distance E between it and the walls of the cell is between 5 and 25 cm, and more preferably between 10 and 20 cm. A too small distance leads to significant losses of load which can be crippling. Too much distance leads to flow rate too low, and therefore insufficient cooling rate. A distance of about 15 cm was found to be very satisfactory.

In a variant of the invention, said first means (which are typically ventilation means) can produce a downward flow in the or each said duct and an upward vertical flow along said walls (2A, 2B) of the cell ( 2). In another variant of the invention, said first means can produce an upward flow in the or each said duct and a vertical flow down along said walls (2A, 2B) of the cell (2).

The ventilation means (101) are blowing means, such as a fan, when seeking to create an upward flow along the walls (2A, 2B) and suction means when seeking to create a downflow along the walls (2A, 2B).

Preferably, when said vertical flow is ascending along the walls (2A, 2B) of the cell (2) (and therefore descending in the conduit or conduits), the so-called "open" end (104) of the (or of each ) conduit (103) may be provided with a diffuser (108) adapted to promote upward deflection of the fluid flow exiting the conduit by said end. The diffuser is advantageously such that it reduces the pressure drop at the so-called open end (104) of (or each) conduit (103).

The conduit is preferably made of a flexible material, high modulus, able to withstand temperatures of less than or equal to about 250 ° C and the blowing pressure, such as an aromatic polyamide fiber (such as Kevlar® ). Said material may be a composite, such as a multilayer. Said material is preferably still sealed in order to reduce in particular the pressure losses along said conduit. For this purpose, said material may be, for example, a multilayer composite comprising a flexible fabric (such as a Kevlar® fabric) and a waterproof layer (such as an aluminum layer). The use of a multilayer comprising a flexible layer and an aluminum layer (on the outside surface of the duct) also makes it possible to reflect the thermal radiation coming from the walls of the duct. the cell and thus avoid excessive heating of the underlying flexible layer.

The device of the invention (100) is preferably removable. It advantageously comprises support elements (105) which make it possible to manipulate and position it above a cell.

The device according to the invention is suitable for implementing the cooling method of the invention.

• la mise en place du dispositif de refroidissement (100) de l'invention ;
• le production d'un flux de fluide de refroidissement à l'intérieure de l'alvéole (2).

The device according to the invention can be used for cooling a furnace (2) of a rotating furnace, and in particular in a cooling method of a furnace (2) rotating furnace comprising:

• placing the cooling device (100) of the invention;
• producing a flow of cooling fluid inside the cell (2).

• la mise en place du dispositif de refroidissement (100) de l'invention ;
• le déploiement du moyen de confinement (103), notamment à l'intérieure de l'alvéole (2) ;
• le production d'un flux de fluide de refroidissement à l'intérieure de l'alvéole (2) à l'aide du ou des moyen(s) de ventilation (101).

In particular, the device according to the invention can be used in a cooling method of a furnace (2) of a rotating furnace comprising:

• placing the cooling device (100) of the invention;
• the deployment of the confinement means (103), in particular inside the cell (2);
• producing a flow of coolant fluid inside the cell (2) using the means (s) of ventilation (101).

These operations are normally performed after the removal. cooked carbonaceous blocks and dust contained in the cell.

The deployment of the conduit may follow a predetermined progression or be controlled according to measurable parameters such as the temperature of the walls of the cell.

testing

Cooling tests of a cell of a rotating furnace were carried out with a device of the invention comparable to that shown in FIGS. 3 and 4. In these tests, the cell had a depth of 4.76 m. and an interior section of 23.7 m ² . The cooling fluid was more or less loaded with moisture. The speed of the air flow was typically 5 to 10 m / s. The air flow was about 3 m ³ / s per fan (and therefore 6 m ³ / s total). The average distance E between the walls of the cell and the duct (103) was about 15 cm. The flow was descending into the ducts and ascending along the walls of the cell.

The cooling of the cell was measured using thermocouples stuck in its walls. The initial temperature of the bottom of the cell was about 130 to 200 ° C, depending on the position in the direction of fire.

Without a cooling device, the time required for the bottom temperature of the cell to drop to 20 ° C was typically 40 hours. With the device of the invention, this time could be reduced to values of the order of 10 hours.

The device of the invention proved to be quiet.

Claims (26)

1. Method of cooling a pit (2) of a ring furnace, said pit (2) comprising walls (2A, 2B), characterised in that it comprises the production of a flux F of cooling fluid inside the pit (2) and in that at least a part Fr of said flux F flows in a substantially vertical manner along determined surfaces of the walls (2A, 2B) of the pit (2).
2. Method according to claim 1, characterised in that said flux F is forced.
3. Method according to claim 2, characterised in that the forced flux is produced by blowing or suction of said cooling fluid.
4. Method according to any of claims 1 to 3, characterised in that the flow velocity of said fluid in said part Fr of said flux F is between 2 and 20 m/s.
5. Method according to any of claims 1 to 4, characterised in that the fluid flow rate of said flux is between 1 and 10 Nm³/s.
6. Method according to any of claims 1 to 5, characterised in that said vertical flow is upward.
7. Method according to any of claims 1 to 5, characterised in that said vertical flow is downward.
8. Method according to any of claims 1 to 7, characterised in that said flux F comprises a part Fo which is substantially parallel to the part Fr and circulated in the opposite direction.
9. Method according to any of claims 1 to 8, characterised in that said fluid contains air.
10. Method according to any of claims 1 to 9, characterised in that said fluid contains water.
11. Device (100) for cooling a pit (2) of a ring furnace, said pit (2) comprising walls (2A, 2B) and a base (2C), characterised in that it comprises:

    - at least one first means (101) capable of producing a flux F of cooling fluid inside the pit (2);

    - at least one second means (103) capable of inducing a substantially vertical flow of at least a part Fr of said flux F along determined surfaces of the walls (2A, 2B) of the pit (2).
12. Device according to claim 11, characterised in that said first means is a ventilation means.
13. Device according to claim 11 or 12, characterised in that said second means is a confinement means, capable of reducing the flow cross-section S of said flux F in the vicinity of the pit walls, so as to induce a rapid flow of said fluid in a substantially parallel direction to said walls.
14. Device according to claim 13, characterised in that said confinement means (103) is removable.
15. Device according to claim 13 or 14, characterised in that said confinement means (103) are retractable.
16. Device according to claim 15, characterised in that it comprises extension means (106, 107) to extend or retract said confinement means (103).
17. Device according to any of claims 13 to 16, characterised in that said confinement means (103) is a duct, wherein a first end is joined to, or to each, said ventilation means (101) and wherein a second end (104) may be placed inside the pit (2).
18. Device according to claim 17, characterised in that said duct is in the form of bellows or an accordion.
19. Device according to claim 17 or 18, characterised in that the dimensions of said duct are such that the average distance E between said duct and the walls (2A, 2B) of the pit (2) is between 5 and 25 cm.
20. Device according to any of claims 17 to 19, characterised in that said first means are capable of producing a downward flux in the or each duct and an upward vertical flux along said walls (2A, 2B) of the pit (2).
21. Device according to claim 20, characterised in that said second end (104) is equipped with a diffuser (108) capable of favouring an upward deflection of the fluid flux from the duct via said end.
22. Device according to any of claims 17 to 19, characterised in that said first means are capable of producing an upward flow in the or each duct and a downward vertical flow along said walls (2A, 2B) of the pit (2).
23. Device according to any of claims 17 to 22, characterised in that the or each duct (103) is such that it can be extended up to a distance D from the base (2C) of the pit less than approximately 50 cm.
24. Use of the cooling device (100) according to any one of claims 11 to 23 for cooling a pit (2) of a ring furnace.
25. Use of the cooling device (100) according to any one of claims 11 to 23 to bring into operation the method according to any one of claims 1 to 10.
26. Method of cooling a pit (2) of a ring furnace comprising :

    - positioning the cooling device (100) according to any one of claims 11 to 23 ;

    - producing a flux of cooling fluid within the pit (2).

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