EP0566497A1 - Air knife device for regulating a metal deposit - Google Patents

Abstract

Device for controlling the thickness of a metal deposit formed on a strip (B) leaving a galvanising bath (1), comprising at least one nozzle (L1, L2) for blowing air through a slot (5) arranged between the opposed and slightly set apart ends of two jaws (41, 42). According to the invention the slot (5) for forming the air knife (A) is bounded by two plane faces (51, 52) parallel to each other, defining the direction (50) of the air knife (A), and one of the said faces (51) is arranged on a deformable lip (53) lying inside a cavity (43) arranged at the end of a first jaw (41) and capable of sliding along a plane supporting face (44) substantially perpendicular to the direction (50) of the air knife (A) while being deformed under the action of means (6) for adjusting the width of the slot, the plane face (51) being moved parallel to itself. <IMAGE>

Description

The present invention relates to an air knife device for regulating, in a hot-dip galvanizing line, the thickness of the zinc deposit on a strip leaving the galvanizing bath.

Air knife type systems have been known for a long time. They conventionally comprise two blowing nozzles disposed respectively on one side and on the other of the strip to be galvanized, in the zone where it emerges from the galvanizing bath. These two air knives are blown on each side of the strip. These nozzles extend over the entire width of said strip, the plane of said air knives being substantially perpendicular to the main plane of the strip. The thickness of zinc deposit obtained depends on the force of impact of the air knives on the strip which can be adjusted by acting on the air pressure in the nozzle or on the distance from the nozzle to the strip.

Such a nozzle is described, for example, in document FR-A-2,090,111 and generally comprises a supply and distribution chamber for the air opening into an acceleration chamber, limited by two jaws converging towards each other to an opening limited by two opposite lips spaced apart, for the formation of a blade of airflow in the direction of the strip.

In this arrangement, one of the jaws is fixed and the other jaw can deform under the action of a plurality of pushers distributed over its entire length so as to vary the thickness of the fluid blade from the edges to the center of the metal strip. Each pusher is associated with an adjustment member controlled individually by a rod extending above the zinc bath and, therefore, subjected to the radiation thereof. Such an adjustment mode is therefore not very precise and can hardly be controlled remotely.

On the other hand, to vary the thickness of the air gap, the movable jaw, which is embedded at its base, on the side opposite the opening, on the wall of the distribution chamber, is provided with a thinning or a slit allowing it to deform, by pivoting around this slit, to adjust the width of the air knife. It follows that the profile of the latter, in cross section, flares more or less depending on the adjustment of its thickness and that the pressure of the jet on the strip can vary.

In another arrangement described in document US-A-3,841,557, the width of the opening can be adjusted by means of a series of electrical resistors placed inside one of the jaws and distributed over the entire length thereof, the jaw being further provided with a cooling system. The adjustment of the width of the slot is obtained by a sort of bimetallic strip effect and can therefore be controlled remotely but its amplitude is necessarily limited. In addition, such an arrangement is quite complicated and expensive.

The invention overcomes such drawbacks and therefore relates to a new device for forming an air space for regulating a metallic deposit which makes it possible, by simple means, to ensure dynamic adjustment of the thickness. of the air gap during the movement of the strip, such adjustment can be carried out remotely. In addition, the air outlet slot has a rectangular section which makes it possible to obtain a real knife effect and this profile is not modified by the adjustment of the thickness of the slot.

In general, the device therefore comprises at least one nozzle for blowing a gaseous fluid such as air, associated with a distribution chamber connected to an air supply circuit and opening into a shaped opening. slit extending transversely over the entire width of the strip and bounded by two closely spaced opposite lips, formed respectively at the ends of two jaws, respectively a first jaw and a second jaw, converging towards each other from the outlet from the distribution chamber to the slot for the formation of the air space, in a mean direction transverse to the plane of travel of the strip B, at least one of said jaws being elastically deformable and associated with means of adjustment of its profile, distributed over its entire length for adjusting the width of the slot.

According to the invention, the slot for forming the air gap A is limited by two plane faces parallel to each other, defining the direction of the air gap A, and that one of said limiting faces is formed on a deformable lip consisting of a profile of flexible elastically deformable material, extending inside a recess formed at the end of a first and limited jaw, on the upstream side in the direction of air blowing , by a flat holding face substantially perpendicular to the direction of the air gap A, said profile comprising, on the upstream side, a corresponding guiding and sealing face, applied against said holding face, said profile deforming under the action of the means for adjusting the width of the slot with displacement of the flat face parallel to itself and sliding of the guide face along the jaw holding face.

In a particularly advantageous manner, the flat face of the deformable lip extends, in the direction of air blowing, over a distance equal to several times the maximum width of the slot. The opposite face of the fixed lip is preferably formed on a bulge of the second jaw and extends substantially over the same width as the deformable lip.

In a preferred embodiment, the flexible profile constituting the deformable lip comprises a part in the form of an elongated strip on which the flat face limiting the slot is formed and, at least on the upstream side, a stiffening rib on which is formed the guide face applied against the holding face.

Preferably, the means for adjusting the width of the slot consist of a plurality of jacks, for example hydraulic or pneumatic or grease, regularly distributed over the entire length of the deformable lip and these jacks are actuated individually by an automatic system. adjusting the width of the opening over the entire length thereof according to the various parameters determining the thickness of the metal deposit. In particular, such an automatic system can comprise a single gauge, movable over the width of the strip, or else a plurality of gauges, regularly distributed, for measuring the thickness of the deposit on the strip after passing in front of the nozzle (s) , the gauge or gauges being associated with means for controlling the position of the adjustment jacks as a function of the thickness of deposit noted by said gauges.

To adjust the width of the opening, the automatic system takes into account, in particular, the vibrations of the tape measured in relation to an average position as well as the temperature and pressure of the air in the distribution chamber, and controls the position of each adjustment means using a sensor associated with it.

In a particularly advantageous embodiment, the first jaw for supporting the deformable lip extends in a substantially vertical direction and parallel to the strip B leaving the galvanizing bath and that the second jaw extends in a direction substantially parallel to the surface of the bath.

Furthermore, the adjustment jacks are preferably placed in a recessed part formed on the external face of the first jaw, and an insulating screen, fixed on the first jaw, is interposed between the strip B and the jacks and closes towards outside the hollowed out part, the latter being associated with air blast cooling means.

On the other hand, to ensure perfect regulation of the air gap, it is necessary for the slot to be perfectly clear over its entire length. For this purpose, it is advantageous to associate with each nozzle a device for cleaning the slot comprising a knife penetrating between the opposite faces of the two lips extending over the entire width of these, said knife being mounted on a carriage movable along the two jaws over the entire length of the slot and associated with means for controlling its movement alternately in one direction and in the other.

The invention also relates to galvanizing equipment comprising such a system.

• - la Figure 1 est une représentation schématique d'un équipement de galvanisation à chaud comportant un système à lames d'air conforme à l'invention ;
• - la Figure 2 est une vue en coupe des buses de soufflage d'un système conforme à l'invention ;
• - la Figure 3 est une vue selon la ligne III-III de la Figure 2.
• - la Figure 4 est une représentation schématique en perspective du dispositif équipé de moyens de nettoyage.

The following description of a particular embodiment of the invention is purely illustrative and not limiting. It must be read in conjunction with the appended drawings in which:

• - Figure 1 is a schematic representation of a hot-dip galvanizing equipment comprising an air knife system according to the invention;
• - Figure 2 is a sectional view of the blowing nozzles of a system according to the invention;
• - Figure 3 is a view along line III-III of Figure 2.
• - Figure 4 is a schematic perspective representation of the device equipped with cleaning means.

The galvanizing equipment shown schematically in Figure 1, comprises, as usual, an elongated tank filled with a galvanizing bath 1 of molten zinc in which a strip B is passed out of a conventional processing line 12, by example, heat treatment furnaces, followed by a cooling zone 13.

The path of the strip inside the bath 1 is determined by deflector rollers 15 ′ and a lower roller 15 immersed in the bath 1. Rollers 16 guide and stabilize the strip B which leaves the bath in a substantially vertical direction.

Immediately after leaving the galvanizing bath 1, the strip B passes through a device for regulating the thickness of the zinc deposit comprising two nozzles L1, L2, placed on either side of the strip B and projecting on each face from this, a flat air layer directed along a plane substantially perpendicular to the strip B. This is then directed to the next installation, for example a skin-pass rolling mill 14.

Figures 2 and 3 show in detail an air knife blowing nozzle S according to the invention, respectively in cross section and in front view.

As shown in Figure 2, the device S comprises two identical nozzles L1 and L2 respectively disposed on either side of the strip B. Each nozzle L1 (L2) is connected to a circuit 2 for supplying pressurized air which opens into a chamber 3 making it possible to distribute the air flow uniformly and to homogenize the pressure over the entire length of said nozzle L1 (L2).

The chamber 3 has, for example, a rectangular parallelepiped shape whose bottom is substantially horizontal and is provided, on the side of the galvanizing bath 1 and the strip B, with an opening 31 for the expulsion of air into a chamber acceleration 4 limited by two jaws 41,42, fixed on the walls of the chamber 1, on either side of the opening 31, and the internal faces of which converge towards each other so that the cross section of the chamber 4 gradually narrows to an outlet opening 5 limited by two opposite lips 51, 52, slightly spaced, which are mé swam, respectively, on the opposite ends of the two upper 41 and lower 42 jaws.

Preferably, the lower jaw 42 extends horizontally above the galvanizing bath 1 and towards the strip B while the upper jaw 41 extends substantially parallel to the strip B in the direction of the jaw 42 with which it defines the opening 5 of the nozzle L1 (L2). The opposite parts of the jaws 41 and 42 converge towards each other up to the opening 5 so as to define, for the air coming from the chamber 3, a throttling and acceleration zone of the air which is evacuated through the opening 5. To ensure a good distribution of the air coming from the chamber 3, a perforated sheet 32 is interposed in the opening 31.

The upper jaw 41, which extends in a direction substantially parallel to the strip B, is provided, at its lower end opposite the lower jaw 42, with a housing 43 limited, on the side of the chamber 3, by a vertical wall 44.

In the example shown, the upper jaw 41 consists of an elongated part fixed to the front wall 20 of the distribution chamber 3 and extended, at its base and on the side of the chamber 4, by a plate 45 which descends to the below the level of the lower end of the jaw 41 so as to limit, with the latter, the housing 43 in which is placed a profile 53 of flexible, elastically deformable material, the lower face 51 of which constitutes the movable lip of the slot 5.

The height of the housing 43 determined by the vertical face 44 of the plate 45 must be slightly greater than the amplitude of adjustment of the slot 5 which it is desired to obtain.

Furthermore, the lower edge of the plate 45 is rounded and is connected by an inclined face 55 of the profile 53 to the upstream edge of the horizontal face 51. In the same way, the upper face of the lower jaw 42, facing the chamber 4, is provided with a bulge 47 which rises slightly, by an inclined face 56, up to a horizontal face 52 placed opposite the horizontal face 51 of the section 53 and constituting the fixed lip of the slot 5.

Thus, the two opposite faces 55, 56 constitute a nozzle which converges towards the slot 5.

The profile 53 preferably has a U-shaped section and therefore comprises a horizontal part in the form of an elongated strip stiffened by two vertical ribs, respectively internal and external, the internal rib, turned towards the side of the chamber 4, being limited by a vertical face 54 which is applied against the vertical face 44 of the plate 45.

Furthermore, the upper jaw 41 comprises, on the side facing the band B, a hollowed out portion 46 in which are placed a plurality of jacks 6 of the hydraulic, pneumatic or grease type, and distributed regularly over the entire length of the jaw 41 , as shown in Figure 3.

Each cylinder 6 is double-acting and comprises a piston displaceable inside a body 61 fixed on the jaw 41 and a rod 62 directed vertically downwards and the end of which is fixed on a pusher 63 mounted sliding vertically in the lower part of the jaw 41 and the lower end of which is fixed to the profile 53.

Under the action of the jacks 6 and the respective pushers 63, the section 53 deviates more or less from the opposite end of the lower jaw 42, which makes it possible to adjust the width of the slot 5. By adjusting the positions of the pushers 63 by means of their respective jack, the longitudinal profile of the profile 53 and, consequently, the height of the opening 5 can be varied over the entire length thereof. It is thus possible to adjust the impact force of the air gap and, consequently, the thickness of the zinc deposit over the entire width of the strip B.

Thanks to this arrangement, the profile 53 slides vertically along the vertical face 44 of the housing 43 on which the face 54 of the profile remains applied, the lower edge of the plate 45 thus constituting a sealing skirt which covers the corresponding edge of the flexible section 53 while avoiding the passage of air between the latter and the jaw 41.

Furthermore, the lower face 51 of the section 53, which constitutes the movable lip limiting the slot 5, extends horizontally over a fairly large distance relative to the height of the slot and the horizontal face 52 of the lower jaw 42, placed opposite face 51, covers the same distance.

As a result, the slot 5 has a rectangular cross section of great length relative to its height, which ensures regulation of the air flow, in the manner of a nozzle. To avoid a pressure drop resulting from the pressure drop, the optimal length of the slit should be between four and six times its height.

Furthermore, when adjusting the height of the slot 5, the deformable lip 53 slides along the retaining face 44 and the horizontal face 51 of the profile 53 therefore moves parallel to itself and to the face 52 of the lower jaw 42, the slot 5 retaining a rectangular cross section over its entire length.

The air knife thus guided, over a certain distance between the parallel faces 51, 52, has less tendency to flare and retains all of its impact force with a knife effect, which makes it possible to ensure precise regulation. the thickness of the zinc coating.

To ensure the adjustment of the profile of the deformable lip 53, it is possible to use a fairly large number of jacks 6, for example from 10 to 30, distributed over the entire length of the jaw and whose spacing is such that the difference in width of the opening 5 between two successive cylinders does not exceed one millimeter.

Cylinders 6 are electronically controlled either by an outside operator acting on a console, or by means of an automatic system for controlling the width of the opening 5 at each cylinder 6, for example as a function of the thickness of the metal deposit on the strip B. This thickness can be controlled in real time by thickness gauges (not shown) distributed over the entire width of the strip B, possibly in a number equal to that of the jacks, so as to control the thickness of the deposit on the area next to each cylinder.

Each cylinder 6 is associated with a displacement sensor 64, for example of the inductive type, which measures the displacement of the piston of the cylinder. It is also possible to use non-contact capacitive sensors 64 ′ arranged on the lower jaw 42 so as to measure the width of the opening 5.

However, the efficiency of the air knife thus produced does not only depend on the width of the opening 5, but also on the pressure and the temperature of the air.

To ensure good distribution of the air over the entire length of the chamber 3, the latter is supplied, as indicated diagrammatically in FIG. 3, from a manifold 2 extending all along chamber 3 and communicating with it by several pipes 21 regularly distributed. Pressure sensors, also distributed over the length of the chamber 8, make it possible to check the uniformity of the pressure which can be obtained, for example, by placing an adjustable diaphragm 22 at the outlet of each tube 21.

The air temperature is also measured by one or more sensors 33 distributed over the chamber 3 and the temperature of the metal part, for example of the jaw 41, is also measured.

Indeed, the strip B leaving the galvanizing bath heats the device by radiation and it is therefore necessary to avoid too great a rise in temperature of the adjustment means 6 and of the sensors and, for example, to maintain them at a temperature of around 40 °. To this end, an insulating screen 23 can be interposed between the strip B and the jaw 41. In addition, the latter can be provided with channels 24 for circulation of a cooling fluid. But one can also place along the upper part of the chamber 3 a ramp 25 for blowing air into the space between the insulating panel 23 and the jaw 41, so as to cool the latter as well as the assembly cylinders 6 when these are placed outside the jaw.

It is thus possible to maintain the temperature of the entire equipment at a correct and uniform level. Furthermore, the measurement of the temperature of the jaw 41 makes it possible to take account of the expansions of the latter in the automatic system for controlling the height of the opening 5.

But, to obtain perfect control of the thickness of the metal deposit, it is useful to also take into account the vibrations of the strip B which, although maintained by the stabilizing rollers 16, can move slightly on either side from an average position.

Sensors 35 can therefore be distributed over the length of the jaw, for example one at each end and one in the middle, to measure the vibrations of the strip on either side of a mean position, the measurement being taken into account in real time in the control of the opening 5. The efficiency of the air gap, which also depends on the distance of the strip from the nozzle, is thus increased.

It can therefore be seen that it is possible to modify the opening profile of the nozzles as a function of the width of the strip, of the thermomechanical deformations of the air knives and, in general, of all the parameters on which their effectiveness depends. . The regularity of the zinc deposit is therefore considerably improved. In addition, it is possible to integrate the device into a control loop which allows automatic regulation of the coating thickness.

It should also be noted that the device according to the invention makes it possible, if necessary, to make a non-uniform adjustment of the thickness of the deposit over the width of the strip since each actuator for adjusting the opening of the nozzles corresponds to a zone determined over the width of the strip can be adjusted independently of the others.

The device can also be advantageously supplemented by cleaning means. By way of illustration, FIG. 4 shows such equipment provided with means 26 allowing cleaning of the slot 5, which mainly comprise a shuttle or carriage 7 moved by means of cables 72 along the face of the lip 51 and which is opposite strip B. This carriage carries a knife 71 of a length corresponding substantially to the width of the lip and which enters the opening 5. The cables pass over pulleys 70 and are actuated by motorized drive means 73 allowing the shuttle 7 to move with the knife 71, in one direction or the other, along the opening 5, which performs automatic cleaning and, therefore, maintaining the width thereof. It will be noted that the passage of the knife along the slot 5 is rapid and does not disturb the operation of the air gap, so that the coating remains regular in thickness and in appearance.

Such cleaning means make it possible to avoid manual interventions necessary in the devices of the prior art, which makes it possible to avoid risks for the personnel. In addition, cleaning is performed much more precisely than in the case of manual cleaning.

The slot cleaning device 5 which has just been described is particularly effective and could be used in other air knife devices.

In FIG. 4, the displacement sensors 64 of the jacks 6, the temperature detectors 33 and 34, the detector 35 for measuring the vibrations of the band B have been represented.

The reference signs, inserted after the technical characteristics mentioned in the claims, have the sole purpose of facilitating the understanding of the latter and in no way limit their scope.

Claims (17)

1. Device for regulating the thickness of a metal deposit formed on a strip (B) at the outlet of a galvanizing bath (1) comprising at least one nozzle (L1, L2) for blowing a gaseous fluid such only air, associated with a distribution chamber (3) connected to an air supply circuit (2) and opening into a slot-shaped opening (5) extending transversely over the entire width of the strip (B) and limited by the opposite and narrowly spaced ends of two jaws, respectively a first jaw (41) and a second jaw (42), converging towards each other from the outlet (31) of the distribution chamber (3) to the slot (5) for the formation of the air space (A) in an average direction (50) transverse to the running plane of the strip (B), at least one of said jaws ( 41) being elastically deformable and associated with means (6) for adjusting its profile, distributed over its entire length for adjusting the width of the slot (5),
characterized in that the slot (5) for forming the air space (A) is limited by two plane faces (51, 52) parallel to each other, defining the direction (50) of the air space (A ), and that one of said limiting faces (51) is formed on a deformable lip (53) consisting of a profile made of elastically deformable flexible material, extending inside a recess (43) formed at the end of a first jaw (41) and limited, on the upstream side in the air blowing direction, by a flat holding face (44) substantially perpendicular to the direction (50) of the air gap (A), said profile (53) comprising, on the upstream side, a corresponding guiding and sealing face (54), applied against said retaining face (44), said profile (53) being deformed under the action of means (6) for adjusting the width of the slot with displacement of the flat face (51) parallel to itself and sliding of the face guide (54) along the holding face (44) of the jaw (42). 2. Regulating device according to claim 1, characterized in that the planar face (51) of the deformable lip (53) extends, in the air blowing direction, over a distance equal to several times the maximum width of the slot (5). 3. Regulating device according to claim 2, characterized in that the flat face (51) of the deformable lip (53) extends over a distance of the order of five times the maximum width of the slot (5) . 4. Regulating device according to one of the preceding claims, characterized in that the second face (52) for limiting the slot (5), opposite the first face (51), is formed on a bulge (46) from the end of the second jaw (42) and extends, in the direction of air blowing, over the same distance as the first face (51), parallel to the latter. 5. Regulating device according to one of the preceding claims, characterized in that the means (6) for adjusting the width of the slot (5) are constituted by a plurality of jacks, for example hydraulic or pneumatic or grease , distributed regularly over the entire length of the deformable lip (53). 6. Regulating device according to one of the preceding claims, characterized in that the profile (53) constituting the deformable lip comprises a portion in the form of an elongated strip on which the flat face (51) for limiting the slot is formed. (5) and, at least on the upstream side, a stiffening rib on which is formed the guide face (54) applied against the holding face (44). 7. Regulating device according to one of the preceding claims, characterized in that the internal face, facing the chamber (3), of the first jaw (41) carrying the deformable lip (53), is covered with a plate (45) extended beyond its end, so as to provide, on the external side, the retaining face (44) limiting the recess (43) in which the deformable lip (53) is placed by forming a skirt d sealing opposing the passage of air between said lip (53) and the first jaw (41). 8. Regulating device according to one of the preceding claims, characterized in that it is associated with an automatic system for adjusting the width of the opening (12) over the entire length thereof according to the different parameters determining the thickness of the metal deposit. 9. Regulating device according to claim 8, characterized in that the automatic adjustment system comprises a plurality of gauges for measuring the thickness of the deposit on the strip (B) after passing in front of the nozzle (s) (L1, L2 ), associated with means for controlling the position of the adjustment cylinders (6) as a function of the thickness of deposit noted by said gauges. 10. Regulating device according to one of claims 8 and 9, characterized in that it comprises means for measuring the vibrations of the strip (B) with respect to an average position and that the automatic system takes account of the vibrations measured for adjusting the width of the opening (5). 11. Regulating device according to any one of claims 8 to 10, characterized in that it comprises means for measuring the temperature and the pressure of the chamber (3), as well as means for detecting the displacement of the jacks (6), and that the automatic system takes these various measures into account for adjusting the width of the opening. 12. Regulating device according to one of the preceding claims, characterized in that the jacks (6) for adjusting the position of the deformable lip (53) are placed in a recessed part (46) formed on the external face of the first jaw (41). 13. A regulating device according to claim 12, characterized in that each cylinder (6) actuates a pusher slidably mounted on the end of the first jaw (41) and fixed, at its opposite end, on the internal face (56 ) of the profile (53) opposite the face (51) for limiting the slot (5). 14. Control device according to one of the preceding claims, characterized in that the first jaw (41) for supporting the deformable lip (53) extends in a substantially vertical direction and parallel to the strip (B) coming out of the galvanizing bath (1) and that the second jaw (42) extends in a direction substantially parallel to the surface of the bath (1). 15. Regulating device according to claim 14, characterized in that, the adjusting jacks (6) being placed in a recessed part (46) formed on the external face of the first jaw (41), an insulating screen (23 ), fixed on the first jaw (41) is interposed between the strip (B) and the jacks (6) and closes the hollowed out part (46) outwards, the latter being associated with means (25) for cooling by air supply. 16. Control device according to one of the preceding claims, characterized in that each nozzle (L1) (L2) is provided with a slot cleaning member (5) comprising a knife (71) penetrating between the faces opposite (51) (52) of the two lips extending over the entire width of these, said knife (71) being mounted on a carriage (7) movable along the two jaws (41, 42) over the entire length of the slot (5) and associated with means (72, 73) for controlling its movement alternately in one direction and in the other. 17. Galvanizing equipment comprising an air knife device according to one of the preceding claims.

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