DE20114136U1 - Device for cooling material by generating a flat jet - Google Patents

Abstract

The invention relates to a device for cooling plate or strip-type material by creating a fan jet that is directed onto the material to be cooled. Said device comprises: a first housing (2) consisting of cast steel, which extends over the width of the fan jet; a strip (6), which is connected to a first wall (3) of the first housing (2) and together with a second wall (4) of the first housing (2) forms a fan jet nozzle; a second housing (11) consisting of cast steel, which is connected to the first housing (2) at a distance from the strip and has at least one connection (15) for introducing a cooling medium; and a distributor plate (15) provided with passages (14), which is positioned between the two housings (2, 11), separating the interior chambers of the latter from one another.

Description

PATENT ATTORNEYS ZENZ, HELBER, HOSBACH & PARTNER ■ HUYSSENALLEE 58-64 · D-45128 ESSEN Device for cooling material by generating a Flat jet

The invention relates to a device for cooling plate or web-shaped material by generating a flat jet directed at the material to be cooled.

Such devices are used primarily for the controlled cooling of sheets and strips in the steel processing industry. Another area of application is plastics processing.

The invention is based on the object of creating a device of this type which has a large processing width and is nevertheless able to carry out the cooling process very uniformly and in this way guarantee a high processing quality.

To achieve this object, the device according to the invention is provided with

- a first housing made of cast steel which extends over the width of the flat jet,

- a strip which is connected to a first wall of the first housing and together with a second wall of the first housing forms a flat jet nozzle,

- a second housing made of cast steel, which is connected to the first housing at a distance from the bar and has at least one connection for introducing a cooling medium, and

- a distribution plate provided with through-openings, which is arranged between the two housings and separates their interior spaces from each other.

The invention is based on the knowledge that welded structures are no longer able to achieve a very uniform cooling when working with extremely wide flat jets in the order of five meters. Even after careful

During stress relief annealing, the thermal stresses lead to distortion of the welded structure. After all, the nozzle is located a short distance above or below the material to be cooled and is therefore exposed to considerable heat radiation. Distortion of the welded structure has a particularly detrimental effect on the configuration of the nozzle. The nozzle can deform in an arc shape, both in the direction of transport and perpendicular to it. It can also twist. Furthermore, the deformation can lead to the thickness of the flat jet varying across the width of the flat jet. All of these deformations have the disadvantage that the material is cooled unevenly across its width. This results in a corresponding loss of quality.

The invention, on the other hand, works with two interconnected housings made of cast steel that clamp the distributor plate between them. This creates a rigid, torsion-free construction that can withstand high thermal loads even with an extremely wide flat jet without the nozzle becoming deformed. The cooling process is therefore very even, so that high-quality sheets can be produced.

The second housing, which preferably also extends over the width of the flat jet, receives the cooling medium and distributes it evenly to the interior of the first housing via the distributor plate. The nozzle is exposed to the cooling medium equally across the width of the flat jet.

This effect can be further improved by providing the second housing with a plurality of connections for introducing the cooling medium and by providing an area of at least equal to the area of the through-openings of the distributor plate.

Furthermore, the stability of the construction can be increased by lining the interior of the first and/or the second housing with cast iron

The overall result is a relatively flat, upright assembly which, thanks to the cast construction of the two housings and the clamping of the distributor plate, is torsionally rigid and can withstand high thermal loads even at extreme lengths.

The cast webs of the first housing end at a distance in front of the nozzle that is preferably at least one and a half times the length of the nozzle. This ensures that the flow disturbances caused by the cast webs have subsided before the cooling medium enters the nozzle.

The length of the nozzle is preferably 10 mm to 40 mm to counteract jet expansion after exiting the nozzle.

In a further development of the invention, it is proposed that the strip is arranged on the outer surface of the first wall of the first housing. The strip cannot therefore lead to a weakening of the housing construction. In addition, no sealing problems arise. Leaks would impair the uniformity of the flat jet and cause a corresponding reduction in the quality of the work result.

From this point of view, it is particularly advantageous that the strip rests in a metallically sealing manner on the outer surface of the first wall of the first housing.

Preferably, the strip is supported on a shoulder protruding from the first wall of the first housing. This also increases the rigidity of the entire construction.

In a further development of the invention, it is proposed that the thickness of the flat jet, which is preferably 1 mm to 4 mm, can be adjusted using a shim strip arranged between the strip and the shoulder. It has been shown that shim strips are best suited to reliably enable precise nozzle adjustment even with a large nozzle extension.

Preferably, the first wall of the first housing is aligned perpendicularly to the second wall of the first housing. The nozzle is formed between plane-parallel surfaces, one of which is arranged on the strip and the other on the second wall of the first housing. The arrangement can be such that the two housings form an upright assembly arranged perpendicularly to the material to be cooled, with the first wall of the first housing being angled by 40° to 50°, so that the flat jet also hits the material to be cooled at an angle of 40° to 50°.

The invention is explained in more detail below using a preferred embodiment in conjunction with the accompanying drawing. The drawing shows:

Figure 1 shows a vertical section through a device according to the invention.

The device is used to generate a flat jet which is directed against a jet sheet 1. The steel sheet 1 is transported from left to right in Figure 1. The width of the flat jet, measured perpendicular to the plane of the drawing in Figure 1, is five meters.

The device has a first housing 2 made of cast steel, which extends over the entire width of the flat jet. It essentially consists of a first wall 3 and a second wall 4, which are connected to one another via cast webs 5 and end walls (not shown).

A strip 6 is arranged on the outer surface of the first wall 3, which forms a flat jet nozzle with the second wall 4. The first wall 3 is angled and the second wall 4 is guided in such a way that it forms a right angle with the first wall 3 in the nozzle area. This configuration results in the angle at which the flat jet hits the steel sheet 1.

The length of the nozzle in this case is 20 mm.

This ensures that the thickness of the flat jet only increases slightly after it exits the nozzle.

The cast webs 5 end at a distance in front of the nozzle that is several times the length of the nozzle. The disturbances in the flow of the cooling medium caused by the cast webs 5 have therefore already subsided when the cooling medium enters the nozzle. The result is a very uniform formation of the flat jet.

The arrangement of the strip 6 on the outer surface of the first wall 3 of the first housing 2 contributes to increasing the stability of the first housing 2. The arrangement is such that the strip 6 rests against the outer surface of the first wall 3 in a metallic seal. Leaks that could lead to disruption of the flat jet are thus avoided.

The strip 6 is clamped against the outer surface of the first wall 3 by means of a screw 7. In addition, the strip 6 is supported on a shoulder 8 protruding from the first wall 3 of the first housing 2. The height of the nozzle gap, i.e. the thickness of the flat jet, is determined by a shim 9 which is arranged between the strip 6 and the shoulder 8 and is fixed by an additional screw 10. If the nozzle is changed, the shim 9 is replaced.

At a distance from the bar 6, the first housing 2 is screwed to a second housing 11. The latter is also made of cast steel and, like the first housing 2, extends in one piece over the entire width of the flat jet. The second housing 11 is also provided with cast webs 12 on its inside.

A distributor plate 13 is clamped between the two housings 2 and 11. It has passage openings 14 for the cooling medium. The two steel housings 2 and 11 form a rigid composite with the interposition of the distributor plate 13, which remains dimensionally stable even under the prevailing thermal loads. The flat jet can therefore impinge on the steel sheet 1 undisturbed and in a defined formation. This enables an optimal

achieve excellent cooling results, resulting in high material quality.

The second housing 11 is provided with a plurality of connections 15 for introducing the coolant. The coolant enters the interior of the second housing 11 and is distributed evenly across the width of the jet by the distributor plate 13. It then passes through the passage openings 14 into the interior of the first housing 2 and into the flat jet nozzle at its outlet end. The arrangement is such that the connections 15 define a total passage area which corresponds at least to the sum of the passage areas of the passage openings 14, with the distribution of the coolant improving as the ratio increases.

Within the scope of the invention, there are certainly possibilities for modifications. This applies, for example, to the angle at which the flat jet hits the workpiece. The extension of the second housing in the direction of the width of the flat jet does not necessarily have to correspond to that of the first housing, although identical dimensions are preferable with regard to the stability of the overall arrangement. The cast webs of the first and/or second housing can be dispensed with if necessary. Here too, however, the stability of the arrangement is promoted by the cast webs, particularly in the case of wide flat jets. In addition to their strength function, the cast webs also fulfill a function as flow guides. The latter also applies to the distributor plate. The metal seal between the strip and the first housing can be replaced or supplemented by an inserted sealing element.

Claims (10)

1. Device for cooling plate or web-shaped material by generating a flat jet directed at the material to be cooled, with 1. a first housing ( 2 ) made of cast steel, which extends over the width of the flat jet, - a strip ( 6 ) which is connected to a first wall ( 3 ) of the first housing ( 2 ) and together with a second wall ( 4 ) of the first housing ( 2 ) forms a flat jet nozzle, - a second housing ( 11 ) made of cast steel, which is connected to the first housing ( 2 ) at a distance from the bar ( 6 ) and has at least one connection ( 15 ) for introducing a cooling medium, and - a distributor plate ( 13 ) provided with through openings ( 14 ), which is arranged between the two housings ( 2 , 11 ) and separates their interior spaces from one another. 2. Device according to claim 1, characterized in that the second housing ( 11 ) has a plurality of connections ( 15 ) for introducing the cooling medium and that their area corresponds at least to the area of the passage openings ( 14 ) of the distributor plate ( 13 ). 3. Device according to claim 1 or 2, characterized in that the interior of the first and/or the second housing ( 2 , 11 ) is provided with cast webs ( 5 , 12 ) running in the flow direction. 4. Device according to claim 3, characterized in that the cast webs ( 5 ) of the first housing ( 2 ) end at a distance in front of the nozzle which corresponds to at least one and a half times the nozzle length. 5. Device according to one of claims 1 to 4, characterized in that the length of the nozzle is 10 mm to 40 mm. 6. Device according to one of claims 1 to 5, characterized in that the strip ( 6 ) is arranged on the outer surface of the first wall ( 3 ) of the first housing ( 2 ). 7. Device according to claim 6, characterized in that the strip ( 6 ) rests in a metallically sealing manner on the outer surface of the first wall ( 3 ) of the first housing ( 2 ). 8. Device according to one of claims 1 to 7, characterized in that the strip ( 6 ) is supported on a shoulder ( 8 ) protruding from the first wall ( 3 ) of the first housing ( 2 ). 9. Device according to claim 8, characterized in that the thickness of the flat jet is adjustable via a support strip ( 9 ) arranged between the strip ( 6 ) and the shoulder ( 8 ). 10. Device according to one of claims 1 to 9, characterized in that the first wall ( 3 ) of the first housing ( 2 ) is aligned perpendicular to the second wall ( 4 ) of the first housing ( 2 ).