DE202009018702U1 - Nozzle device and strand guiding device with the nozzle device - Google Patents

Abstract

Nozzle device (100) with a nozzle head (110) for atomizing a fluid (220); and with at least one pipeline (120) for supplying the fluid (220) to the nozzle head (110), characterized in that the pipeline (120) has a plurality of cross-sectional constrictions (240 ') in its interior which extend over the length of the pipeline (120 ) are distributed.

Description

The invention relates to a nozzle device with a nozzle head for atomizing a fluid and with a pipe for supplying the fluid to the nozzle head. The invention also relates to a strand guiding device with the nozzle device.

In the strand guiding device of a slab or thin slab continuous casting plant, single-substance and / or multi-substance nozzles, in particular two-substance nozzles, are used for cooling the strand. The strand guiding device consists of a series of segments, the number of which is determined by the respective requirements of the strand. It can consist of up to 20 segments (with corresponding roller conveyor). In a segment of the strand guiding device between 2 to 10 rollers or sub-rollers (rollers with corresponding division) per segment frame (top and bottom) are present.

Between each segment and each roll, so in each space, the nozzles are used to cool the strand. In general, single-fluid nozzles are operated with water and two-fluid nozzles with a mixture of compressed air and water. Depending on the width of the strand guiding device up to 12 nozzles per space are used. Depending on the type of system, up to 10 rolls × 20 segments × 12 nozzles = 2,400 nozzles are used.

Assuming a flow per nozzle of 15 l / min of water, the total amount of water adds up to 36,000 l / min (2,160 m ³ / h). The air flow per nozzle amounts to up to 25 Nm ³ / h, resulting in a total consumption of up to 60,000 Nm ³ / h. The amount of potential savings is very clear at these consumption levels.

From the publication DE 10333477 is a flow channel for liquids is known in which a flow channel limiting wall is formed such that when flowing through a liquid at least one flow region is formed, which has an axial and tangential flow component simultaneously. There is provided a flow channel for liquids or gases, which is designed so that the lowest possible losses in the flow, in particular low friction losses occur.

From the publication DE 1261634 is a method for cooling in the continuous casting by direct application of coolant to the emerging from the continuous casting mold strand in which the coolant flow is changed in strength known. The change in the strength, the pulsation, is such that the coolant flow is switched on and off in certain, relatively short time intervals, but also by the fact that the intensity of the coolant flow is changed periodically. The cooling water is thereby deflected by opening or closing a valve in the supply line or by movable baffles, which impinge the water jet depending on their position on the surface of the strand, or from it. In the supply lines valves or movable baffles, ie active elements must be introduced for this process.

The object of the invention is to provide a low-cost and low-maintenance alternative for generating a pulsation of the flowing fluid for a known nozzle device and for a strand guiding device with such a known nozzle device.

This object is achieved by the subject matter of claim 1. This object is characterized in that the pipeline has in its interior a plurality of cross-sectional constrictions which are distributed over the length of the pipeline.

The geometry of the cross-sectional constrictions causes the fluid flow to be pulsed. Due to the pulsation, the overall flow characteristics of the nozzle device and the nozzle characteristics are improved. This results in an increase in the cooling efficiency and thus results in a high potential for saving the consumption of water and air. Since the cross-sectional constrictions are purely passive elements, can be dispensed with according to the invention on the use of active elements, such as controlled valves. The elimination of active elements, ie moving components, minimizes costs, leads to a significant reduction in wear, increases the intervals between the maintenance intervals and thus leads to longer service life of the nozzle device according to the invention.

According to a first embodiment of the nozzle device, this is characterized in that the cross-sectional constrictions are preferably arranged equidistantly. By this equidistant arrangement advantageously the pulsation frequency can be adjusted, via which the cooling effect can be influenced. The pulsation frequency must reach such a high value that cooling interruptions must be ruled out.

According to a further embodiment, the nozzle device is characterized in that the pipeline distributed over its length a Having a plurality of tapered portions, the tapered ends each represent the cross-sectional constrictions. As a result of the tapering, the fluid in the direction of flow advantageously undergoes a laminar, low-resistance introduction to the cross-sectional constrictions without negatively influencing the overall fluidic properties of the system.

According to a further embodiment, the nozzle device is characterized in that the tapered portions each represent an individual portion of the pipeline and are connectable to each other to form the pipeline. The fact that the individual sections of the pipe are inserted into each other, advantageously results in a geometry that can be flexibly adapted to local conditions.

According to a further exemplary embodiment, the nozzle device is characterized in that the individual sections of the pipeline can be connected to one another such that the outlet opening of a section located upstream in the direction of flow of the fluid is inserted into the inlet opening of a downstream section in the direction of flow of the fluid, wherein the outlet opening is tapered End and the inlet opening are represented by the flared end at the respective sections. Advantageously, by this measure existing installations can be easily adapted without changes to other parts of the system, such as metrological equipment and control and actuators must be made.

According to a further embodiment, the nozzle device is characterized in that the cross-sectional constrictions at least partially on its side facing away from the flow direction of the fluid side have a tear-off edge. At the trailing edge, an edge turbulence, the so-called flow roll, arises, which advantageously ensures that the main fluid flow no longer comes into direct contact with the inside of the tube wall. Thus, the main fluid flow experiences less friction, resulting in laminarization and increasing the effectiveness of the nozzle device.

Further advantageous embodiments of the device of the invention are specified in the subclaims.

The above object is further achieved by a strand guiding device according to claim 10. The advantages of this solution correspond to the advantages mentioned above with respect to the nozzle device.

The description is a total of six figures attached, where

1 a nozzle device with detail enlargement according to a first embodiment,

2 a tapered section of the pipeline,

3 a nozzle device according to a second embodiment in the form of a multi-component nozzle with offset mixing body,

4 a nozzle device according to a third embodiment in the form of a multi-fluid nozzle with attached mixing body,

5 a continuous caster, and

6 an arrangement of the nozzle device in a segment
shows.

The nozzle device according to the invention will be described in detail below with reference to the figures. In all figures, the same technical features are designated by the same reference numerals.

In 1 is a nozzle device 100 with a pipeline 120 in which a plurality of tapered cross-sectional constrictions 240 ' are formed and a nozzle head 110 from which a fluid 220 outlet, shown as a single-fluid nozzle. A detail enlargement in 1 shows a fluid flow 200 at a spoiler edge 250 and a resulting edge turbulence, the so-called flow roll 260 , The pipeline 120 is in individual flow-tapering sections 125 , so-called individual cuts, divided. These individual sections are inter alia by an upstream inlet opening 230 and a downstream in the flow direction outlet opening 240 characterized. Another characteristic of the individual sections is that they are tapered in the flow direction. This allows the outlet opening 240 a section in the inlet opening 230 of the next section. The interleaved sections form the pipeline 120 ,

Through this constructive structure of the pipeline 120 becomes the fluid flow 200 to the nozzle head 110 directed. The fluid flow 200 subject to the cross-sectional constrictions 240 ' a, taking place at intervals, pipe constriction (outlet opening 240 ) and a tube expansion (inlet opening 230 ). This results in a repetitive Speed change of the fluid flow, which leads to a pulsation of the fluid flow. The realization of the pulsation of the fluid takes place by the mechanical properties of the pipeline and requires no moving or controllable components. The pulsation frequency can be determined by means of the number and the respective length of the tapered sections 125 to adjust. To exclude cooling interruptions, the pulsation frequency must have a correspondingly high value.

At the end of each tapered section 125 is the trailing edge 250 formed, as shown in the enlarged detail, the formation of a flow roll 260 causes. The velocity of the fluid flow is adjusted so that the flow roll is maintained and can not enter the fluid flow. This ensures that the main fluid flow through the tapered sections 125 is centralized, can not come into contact with the inside of the pipe wall, thus no friction occurs and thus no turbulent flow of the fluid.

The pulsation in conjunction with the laminarization of the fluid flow causes an improvement in the nozzle characteristics and thus an increase in the cooling efficiency. This increase in efficiency allows, without limiting the cooling effect, a saving of the fluids to be used. Since the consumption values in a strand guiding device can be very high, this results in an enormous saving potential. In 2 is the tapered section 125 with its entrance opening 230 and the exit opening 240 shown. The tapered end protrudes into the inlet opening 230 of the next section and shows the cross-sectional constriction 240 ' , At the end of the section is the spoiler lip 250 educated.

3 shows a nozzle device according to a second embodiment in the form of a multi-material nozzle 100 ' with offset mixing body, in this case a two-fluid nozzle, in which the pipeline according to the invention 120 between nozzle head 110 and mixed body 140 ' is arranged.

A first supply line 150 performs a first substance component and a second supply line 160 performs a second substance component to the mixing body 140 ' , Subsequently, the mixture of first and second substance component by the geometry of the pipeline 120 pulsation and laminarization are imposed and the pulsating fluid is delivered via the nozzle head 110 applied to the element to be cooled. The first and the second supply line may be formed in the form of the pipe according to the invention with the cross-sectional constrictions.

In 4 is the multi-substance nozzle 100 '' formed such that the mixing body 140 ' is placed directly on the nozzle head. At least one of the supply lines 170 . 180 to the mixing body 140 ' is in the form of the pipeline according to the invention 120 educated. The fluid 220 is in each case in the pipeline according to the invention 120 put into pulsation and it sets up a laminar / low-friction fluid flow.

5 provides a strand guide device 400 in a slab or thin slab caster, consisting of a series of segments 410 , the number of which is determined by the particular requirements of the cast strand is composed. Between the rollers are used to cool the strand 430 the nozzle devices according to the invention as single and / or two-fluid nozzles optionally used with all embodiments, see 6 ,

LIST OF REFERENCE NUMBERS

100

nozzle device

110

nozzle head

120

pipeline

125

rejuvenating section

100 '

Multi-substance nozzle with mixed body deposited from the nozzle head

100 ''

Multi-substance nozzle with mixing body placed on the nozzle head

140 '

mixing body

150

Supply line 1

160

Supply line 2

170

Supply line 3

180

Supply line 4

200

fluid flow

210

Flow direction of the fluid

220

fluid

230

inlet opening

240

outlet opening

240 '

Cross-sectional narrowing

250

tear-off edge

260

flow roller

400

A strand guide device

410

segment

420

mold

430

strand

440

Strand guide rolls

450

top

460

bottom

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10333477 [0005]
• DE 1261634 [0006]

Claims (10)

Nozzle device ( 100 ) with a nozzle head ( 110 ) for atomizing a fluid ( 220 ); and with at least one pipeline ( 120 ) for supplying the fluid ( 220 ) to the nozzle head ( 110 ) characterized in that the pipeline ( 120 ) in its interior a plurality of cross-sectional constrictions ( 240 ' ), over the length of the pipeline ( 120 ) are arranged distributed. Nozzle device ( 100 ) according to claim 1, characterized in that the cross-sectional constrictions ( 240 ' ) are preferably arranged equidistantly. Nozzle device ( 100 ) according to one of the preceding claims, characterized in that the pipeline ( 120 ) distributed over its length a plurality of tapered sections ( 125 ) whose tapered ends each have the cross-sectional constrictions ( 240 ' ). Nozzle device ( 100 ) according to claim 3, characterized in that the tapered sections ( 125 ) each an individual section of the pipeline ( 120 ) and connectable to each other to form the pipeline ( 120 ). Nozzle device ( 100 ) according to claim 4, characterized in that the individual sections of the pipeline ( 120 ) are connectable to each other in such a way that the outlet opening ( 240 ) one in the flow direction of the fluid ( 210 ) upstream portion in the inlet opening of a fluid in the direction of flow ( 210 ) downstream portion is inserted, wherein the outlet opening ( 240 ) are represented by the tapered end and the entrance opening by a flared end at the respective portion. Nozzle device ( 100 ) according to one of the preceding claims, characterized in that the cross-sectional constrictions ( 240 ' ) at least partially on their the flow direction of the fluid ( 210 ) facing away from a spoiler edge ( 250 ) exhibit. Nozzle device ( 100 ) according to one of the preceding claims, characterized in that the nozzle device ( 100 ) as a multi-substance nozzle ( 100 ' ), in particular two-fluid nozzle, with a settled mixing body ( 140 ' ), wherein the mixing body ( 140 ' ) through the pipeline ( 120 ) with the nozzle head ( 110 ) connected is. Nozzle device ( 100 ) according to claim 1 to 6, characterized in that the nozzle device ( 100 ) as a multi-substance nozzle ( 100 '' ), in particular two-fluid nozzle, is formed, wherein between the nozzle head end of the pipeline ( 120 ) and the nozzle head ( 110 ) a mixed body ( 140 ' ) is arranged, wherein on the mixing body ( 140 ' ) next to the pipeline ( 120 ) is connected for supplying a first fluid at least one further supply line for supplying at least one second fluid. Nozzle device ( 100 ) according to claim 8, characterized in that the supply line according to the pipeline ( 120 ) is trained. Strand guiding device ( 400 ) in a continuous casting plant for guiding a cast strand after leaving a mold, with upper and lower strand guide rolls ( 440 ) between which the strand is guided; and a cooling device having a plurality of nozzle devices ( 100 ) according to one of claims 1 to 8, which between the strand guide rollers ( 440 ) are arranged for cooling the strand during its passage through the strand guiding device ( 400 ), characterized in that the pipelines ( 120 ) of the nozzle devices ( 100 ) in its interior a plurality of over the length of the pipeline ( 120 ) have distributed cross-sectional constrictions.

Images