EP0846930A2 - Device for uniform feeding of a fluid onto the surface of a workpiece - Google Patents

Abstract

A discharge for a fluid, especially gas, over the flat surface of a work-piece. The discharge comprises a flat array (6) of jets (1,2,3,4) arranged in groups. The distance between individual jets within a single group is less than the distance between jets in neighbouring groups. Each jet has gas guide-vanes (7), and each group of jets discharges a joint vortex covering 360 degrees . The vanes may be fitted to both the inlet and outlet sides of the array. The vanes deflect the gas through an angle of preferably 15 to 45 degrees .

Description

The invention relates to a device for uniform Loading a flat surface of a workpiece, in particular the end face of a ribbon bundle, with a Fluid, especially with a gas, which in the preamble of Claim 1 specified genus.

Such a device as used for the high temperature zone a grate cooler, especially for cement clinker, is to be used, for example, from DE-OS 24 54 202 and has a flat nozzle bottom as well as several punctiform openings in the bottom of the nozzle on the single, discrete gas jets on the plane Straighten the surface of the workpiece; the openings are according to a given pattern on straight lines arranged in the nozzle bottom, so that each row of holes a forms slit-shaped nozzle opening.

Furthermore, one goes for the burner from US-PS 41 55 701 used mixing device in a gas jet creates a swirl and thereby the good combustion brings about the required mixture of gas flows. Would such a device against a baffle arrange them as the flat surface to be treated represents a workpiece, so would on this Baffle a distribution of the heat transfer coefficient adjust as they are for normal slot nozzles results. The only difference from usual straight is that the line of impact and thus the lines which are the maxima of the local heat transfer coefficients connect with each other, are also curved.

Furthermore, from US-PS 42 61 517 and US-PS 38 87 135 Devices known in which the beam to the axis to which the rotation takes place is focused; one would the end face of such a device Blowing the band, so there would be a traffic jam in the center result, so that no unhindered overflow of the end face of the band and therefore no uniform application is more possible with the gas.

The particularly even application of the flat surface a workpiece with a gas plays everywhere a role where heat is generated by means of this flowing gas the workpiece must be transferred because only then uniform heat transfer or possibly also Mass transfer between gas flow and heat guaranteed is without major differences in the local heat transfer coefficient at different temperatures or lead to different heating of the workpiece. This is the case, for example, when heating metal strip coils a big problem. Under a "metal band" one understands sheet metal strips wound into a cylinder, for example made of an aluminum alloy.

To shorten the glow time of such metal coils aimed at heat transfer in a chamber furnace like him for example in the aluminum industry for annealing Light metal strapping is used as high as possible to drive. Now leads the blowing system used to large local differences in heat transfer, so local overheating can occur, the discoloration of the metal strips and also the desired ones impair the metallurgical properties of the strips can.

The usual blowing systems with which a higher one Desired heat transfer, perforated or Slot nozzles on, the vertical on the surface of the Generate collision impinging metal bundle; will local overheating has now been determined, so remains in many cases no choice but to reduce the total volume flow and thereby the high local heat transfer coefficients to avoid.

The solution to this problem is in the German patent 35 03 089 for the special case that a uniform application of a rotationally symmetrical, through several, slot-like openings in a device arranged in a nozzle bottom is achieved, the nozzle jets in the same direction against the surface of action are inclined. This special case applies if the rotationally symmetrical device exactly or at least with sufficient accuracy to the also rotationally symmetrical Be centered on the end face of a band can. In practice, however, this is hardly the case, so that then when a non-rotationally symmetrical loading situation there are significant disadvantages to buying are taking, especially by strong inflow of Edges of the band collar end faces, where then despite the high Expenses impermissible with the device described above Overheating occurs.

These disadvantages are overcome with the device according to the invention avoided because now the nozzle openings for themselves are arranged in groups and within these groups, their application area compared to the usual total application area is small, already sufficient Swirling and as well as a rotational movement in the flow occurs, causing point overheating in the vicinity discrete congestion zones can be avoided.

The new blowing system is therefore particularly suitable for convective heat transfer on the end faces of coils, their arrangement to the blowing system is not from is determined in advance and from batch to batch can change. So the new blowing system has it Advantages of from German patent specification 35 03 089 known device, but without the disadvantages, namely the need for some centering of the blowing system on the coil end faces to be heated in To have to buy.

Another extremely beneficial application for the device according to the invention is the production of a high heat transfer to small parts, such as B. ball bearing rings, that on one surface, essentially one flat layer with a fluid, e.g. B. a cooling gas, to be charged. With the mentioned ball bearing rings arises from the constantly changing in their direction Oblique blasting an extremely even exposure both the inner and the outer ring surface, so that a blowing device after the Invention also for gas jet hardening of ball bearing rings offers. Such a device has the Advantage of the special orientation of the ball bearing rings no requirements were placed on the nozzle system will. It is sufficient, for. B., the rings on an appropriate Roller conveyor past under the blowing device move.

Figur 1

eine Draufsicht auf den Düsenboden mit Blickrichtung von der zu beaufschlagenden Fläche,

Figur 2

einen Schnitt durch den Düsenboden und die zugehörigen Strömungsleitreinrichtungen in einer Ebene senkrecht zum Düsenboden.

The invention is explained in more detail below using an exemplary embodiment with reference to schematic drawings. It shows

Figure 1

a plan view of the nozzle bottom with a view from the surface to be acted upon,

Figure 2

a section through the nozzle bottom and the associated flow guide in a plane perpendicular to the nozzle bottom.

In the exemplary embodiment shown, the are as Four circular nozzle openings (1), (2), (3), (4) to form a nozzle opening group (5). The nozzle base (6) is a flat sheet. Several such groups (5) form the total of Nozzle openings in the bottom of the nozzle. Are on the downstream side Devices for deflecting (7) the nozzle jet (8), with which the jet in the example case shown deflected by 45 ° from the vertical (9) becomes. The deflection devices (7) consist of, in cross section considered the deflected jet, U-shaped curved sheets, which with the created by inclined section Joining surface (10) on the nozzle openings plan nozzle bottom (6) are attached. By the desired deflection angle is created in accordance with the inclined section, in the example shown, as mentioned, 45 °. The projection of the deflected jet streams forms exemplary and according to the invention in the case shown for two adjacent nozzle openings divided the angle 360 ° by the number 4 of the nozzle openings equal to 90 ° (11).

Claims (10)

Device for uniform application of a fluid, in particular a gas, to a flat surface of a workpiece, in particular the end face of a band of coils, with a flat nozzle base provided with nozzle openings, characterized by the following features: a) the nozzle openings are combined in groups in the essentially flat nozzle base, b) neighboring outflow openings of a group have a smaller distance from one another than from the respectively nearest nozzle opening of an adjacent group, c) at the nozzle openings, devices for deflecting the nozzle jets are provided in one direction, which forms an angle with the perpendicular to the flat nozzle base or, in the case of a substantially flat nozzle base, with its flat reference surface. Apparatus according to claim 1, characterized in that the projection of the deflected nozzle jet onto the plane of the nozzle base forms an angle for each nozzle opening with the neighboring nozzle openings in the same nozzle opening group, these angles adding up to a total of 360 ° for all nozzle openings in a group. Device according to at least one of claims 1 and 2, characterized in that the arrangement of the nozzle openings in groups is point-symmetrical with respect to the center of the group. Device according to at least one of claims 1 to 3, characterized in that the deflection of the nozzle jets from the direction perpendicular to the nozzle bottom takes place by means of a corresponding inclination of the nozzle openings. Device according to at least one of the two claims 1 to 4, characterized in that devices for deflecting the jet are arranged on the outflow side of the nozzle openings made in the plane nozzle bottom. Device according to at least one of claims 1 to 5, characterized in that devices for deflecting the jet are arranged on the inflow side of the nozzle openings made in the plane nozzle bottom. Device according to at least one of claims 1 to 6, characterized in that the angle of deflection of the nozzle jets from the perpendicular to the flat nozzle bottom is between 15 ° and 45 °. Device according to at least one of claims 1 to 7, characterized in that the nozzle openings are designed with a circular cross section. Device according to at least one of claims 1 to 8, characterized in that the distance between the closest nozzle openings of adjacent groups of nozzle openings is at least 1.5 times the smallest distance between the closest nozzle openings in a group. Device according to at least one of claims 1 to 9, characterized in that the geometrically free nozzle surface in the projection onto the flat nozzle base or the reference plane of the nozzle base makes up between 2% and 10% of the associated total surface of the nozzle base or its reference plane.

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