DE2143962A1 - Cooling and guiding continuously cast bar - avoiding formation of swellings or holes in the bar at high casting rates - Google Patents

Abstract

Continuously cast steel bar is cooled and guided in the secondary cooling zone of a continuous casting installation in which the bar advances between guide elements bearing against opposite surfaces of the bar which is cooled between the guide surfaces. As it moves the bar is alternately sprayed and cooled longitudinally and transversely by water sprayed onto unsupported surfaces of the bar and is guided on supported surfaces which are kept water-free.

Description

Method and device for cooling by means of spray nozzles and guiding of a strand in the secondary cooling zone of a continuous casting plant. The invention relates to a method and a device for cooling by means of spray nozzles and guiding a Strand in the secondary cooling zone of a continuous casting plant, the strand through guided through guide elements resting on opposite strand surfaces and is cooled between the guide elements.

In the case of continuous casting plants, it is known to pass the strand through at intervals to guide rollers arranged from one another in the strand running direction. Between Spray nozzles are provided from which the strand is supplied with cooling water and is cooled. Due to the ferrostatic pressure and the strength of the roll material a certain roll thickness is required, from which on the one hand a certain Roller spacing and, on the other hand, also the spacing of the splint nozzles in the longitudinal direction of the strand results. In systems on which larger formats are cast, this arrangement leads to excessive size of the unsupported areas between the rollers as well as insufficient heat extraction due to the inherently far apart, spray nozzles arranged between the rollers. This gives rise to the disadvantages of that either the known bulges and breakthroughs arise or the casting speed has to be kept so low that the thick one that has become solidified The strand crust is not deformed or deformed under the influence of ferrostatic pressure. rips. It follows that the aforementioned arrangement does not allow larger formats, e.g. slabs, to be cast with increased casting speed.

It is also known a cooling device in which after one of the indirect cooling, a cooling grate of about the same length is used follows. This filler grate is connected to the short mold and points in the longitudinal direction of the strand extending guide strips, between which mounted horizontally side by side Direct water jet nozzles against the strand with high kinetic energy. The disadvantage of this arrangement is that only a relatively small area is intensively cooled, and the cooling water flowing down impairs the cooling effect and disturbs. Also is that Cooling of the strand over a longer period Period between and under the elongated guide rails is very different, so that strand errors can arise.

The invention is based on the object of the strand in the secondary cooling zone to extract as much heat as possible through intensive, trouble-free cooling while at the same time the best possible support to avoid bulges and breakthroughs and high To achieve casting speeds.

This task is achieved in that the moving strand in longitudinal and transverse direction alternately through water sprayed onto unsupported surfaces is acted upon and cooled and is then guided on supported surfaces, wherein the areas of the supported surfaces are kept essentially free of water.

This way there is an optimal combination of guidance and cooling of the strand, since both in the longitudinal direction and in the transverse direction of the strand cooled and guided surfaces alternately below or next to each other are provided.

The device according to the invention for carrying out the method is characterized in that the 'guide elements are made of grid-like plates with guide surfaces associated with the strand surface and corresponding to their shape exist, the plates between the guide surfaces recesses in the longitudinal direction and transverse directions corresponding to the unsupported surfaces of the strand and spray nozzles are arranged in the recesses, the cooling water through the recesses spray the plate onto the surface of the strand.

Due to the multiple guidance in the longitudinal direction, the Bulging avoided because the strand, seen in the transverse direction, is only relatively short has unsupported surfaces in contrast to the known roller guide, for example, with unsupported widths of up to about 2 m in the transverse direction. Since also If water spray is applied to these short surfaces, a very intensive one takes place Cooling right up to the supported surfaces. The procedure of the alternate Cooling and support also in the longitudinal direction result in the highest possible utilization the existing strand area. Since the strand through a pulling unit through the passed through two opposite guide elements resting on its surface the cooled part of the strand surface comes directly below a transverse one Leadership and thereby becomes a supported surface. Since the supported Surfaces are essentially kept free from it'ctSSC, then a recovery of the strand crust is possible from the previous intensive spray cooling, which results in a possible Crack formation is prevented by cooling down too quickly. It is also essential that the support and guidance of the strand takes place on surfaces and not as e.g. with a roller guide only along a line across the strand.

It is advantageous if the size of the spray nozzles is applied The area roughly corresponds to the size of the unsupported area. This can be done in different ways Way to be achieved. e.g. by selecting spray nozzles with the appropriate spray angle, by setting certain distances from the nozzle to the strand surface, etc.

As a result, cooled and supported surfaces go directly into one another above. It is also useful if the sprayed water also supports the water Rihrungen applied above and to the side of the nozzle in the vicinity of the strand and thereby these parts that are constantly in contact with the hot strand cools.

It is also possible to run the strand through adjacent ones in the transverse direction To apply spray nozzles in such a way that the two beauf hit surfaces almost immediately merge into each other and together roughly the unsupported surface correspond. This is an advantage if, for example, in certain areas of the line no support is required. This can for example in the areas against the edges to be the case with slab strands, where there is a risk of bulging less is given. By eliminating a guide surface between the acted upon Areas, these can be moved closer to each other, which means even better utilization of the available strand area.

It is also important that the water sprayed on is drained off again so that there is no disturbance of the cooling effect of the spray water. Since the under the nozzle located transverse guide surface rests on the strand, would extend over this build up water and prevent proper spraying of the surface. Care must also be taken that the spray fan does not drain is additionally hindered. Therefore, the spray angle of the nozzle and / or their Adjustment made so that the exposed area does not reach the bottom The transverse guide surface is sufficient, i.e. not directly exposed to the spray water will. Next is the lower boundary surface of the recesses in or behind those the nozzles are mounted backwards and inclined downwards trained, at an angle of approx. 10 - 250, so that the sprayed on Water first flows a small distance down the strand and then off the strand is derived away. This water is allowed to the spray fan in the strand running direction do not interfere with the following nozzle and must therefore also be outside the nozzle below Verüfächers can be derived. Additional drain holes can create a drain this Facilitate water. For this purpose, the lower boundary surface and / or the drainage opening should be used be set back via the spray nozzle below.

A particular effectiveness of the process results when the strand on several lying one below the other, each supported by surfaces from one another separate rows of recesses is passed, with a further advantageous Training through a mutual relocation of the recesses, i.e. also the momentary cooled strand surfaces of these rows. Rows of recesses can also be used be offset from one another as seen in the transverse direction of the guided strand surface.

When the strand passes through the grid cooling, the unsupported Width of the strand surface can be changed continuously if according to another feature the invention, the grid-like guide surfaces arranged obliquely to the strand running direction are. The strand can be cooled by constantly changing between supported and unsupported areas can be made even more even.

The manufacturing and maintenance costs of such grid plates can be reduced and the use of highly wear-resistant materials can be significantly simplified are, if, according to another indicator, the grid-like plates over the Line width divided into sub-panels and attached to a support frame in an exchangeable manner are.

Wear-resistant cast iron has proven to be a very good material for the Lattice-like plates have proven their worth because it has both favorable properties in relation to Strength and abrasion combined with thermal resistance. at Slab plants are advantageously only the broad sides of the invention Guide elements out. Swiveling deflector plates are located on the narrow sides well proven for drainage.

If the casting program requires several strand formats, the format is adapted the distance between opposing plates provided adjustable. This can be done with the help of by means known per se hydraulic or mechanical Paths, e.g. by hydraulic cylinders, which the guide plates up to Guide stops or through tension and pressure screws. With such means, too a certain adjustment to the desired strand path can be set.

Further features of the invention emerge from the following description from embodiments that relate to the continuous casting of a slab of steel. There are shown: FIG. 1 a schematic representation of an arrangement of inventive Guide elements in an arch system, Fig. 2 is a partially shown element, 3 shows a section along line II 1-111 of FIG. 2, FIG. 4 shows a section the line VI-VI of Fig. 2 and Fig. 5 is a view of another, partially shown Element.

In Fig. 1, 1 denotes a casting container, from the steel in a water-cooled mold 2 flows. The mold 2 below are those according to the invention Guide elements 3,3 'and 4,4' arranged, each in pairs on opposite sides Surfaces of the strand 5 formed in the mold 2 are in contact. The strand 5 becomes pulled out by a driving straightening unit 6. During his passage through the The strand becomes guide elements through water sprayed onto it by means of spray nozzles 8 chilled.

Figures 2, 3 and 4 show details of the construction. In the View is shown in Fig. 2, a guide element, which consists of a grid-like Plate 3, advantageously made of wear-resistant cast iron. The plate 3 has Guide surfaces 10 assigned to the strand surface and recesses therebetween 11. The strand has unsupported surfaces 16 in their area. As Fig. 3 shows, are the guide surfaces 10 of the shape, for example the curvature of the strand 5, adjusted, which has not yet solidified in this area and around the liquid Core 14 has a relatively thin strand shell 15 ..

In the recesses 11 spray nozzles 8 are arranged, the cooling water Spray onto the unsupported surfaces 16 so that the strand is in the longitudinal direction 18 and transverse direction 19 is alternately acted upon and supported. The The size of the impacted area is chosen so that it is roughly the size of the unsupported Area corresponds to 16.

This can be done by means of wanl eeigr.eter nozzles and their distance to the strand surface can be effected. It is important that the areas of the supported strand surface are kept essentially free of water to allow uncontrolled cooling to avoid. In the present case, the recesses 11 have in the grid-like Plates are square in shape and the area exposed to them is round in shape, as full-cone nozzles be applied. In addition, the nozzles are set so that between the Guide surface 10 and the acted upon surface a small area 20 remains, which is not directly discussed. This prevents the spray cone from being disturbed pent up water. In addition, there are the webs or lower boundary surfaces 21 at an angle 22 downwards and backwards, inclined away from the strand, so that accumulated water can be drained away. Drainage openings can also be found in the webs 23 through which the water drains. The angle 22 is in the present case Embodiment 150, but can depending on the strand format and the amount of cooling water required between 10 and 250. This is definitely a mutual disturbance is prevented by adjacent nozzles or spray fans, the head is located the spray nozzle within the guide walls that are not given. It is in particular important that the rear surface of the guide and the drain opening 23 over the underlying The spray nozzle is set back away from the strand. The side facing the strand 5 Plate 3 is divided into easily exchangeable sub-plates 30,30 'and on one Support frame 31 attached by screw connection.

In Figs. 2 and 4 it is shown how the plate 3 is attached to the steel structure is held and attached. An extension 25 engages in a recess 26 in the plate 3, whereby a support takes place.

The fixation is done by the two pressure screws 27 that the Connect the plate to the structure 24. To change the distance when the format changes To be able to make two opposing guide elements is a lag screw 28 provided. Of course, this fixation or change in distance could also be done with others Means, e.g. by a hydraulic system, which interacts with stops.

In Fig. 5, a plate is arranged obliquely to the strand running direction Guide surfaces 10 shown. These have inclined guide surfaces the advantage that there is a risk of protruding parts or the Tearing open the strand surface, when running under the Puhrungsflächen is reduced.

If it should be indicated, the recesses can be circular or elliptical shape and so e.g. each specific generated by a nozzle Correspond to the form of exposure. About the unsupported stretch of the moving Keeping the strand surface as short as possible can be done, for example, in the mold the recesses closest to them as a width arranged transversely to the strand running direction Run slots and the cooling can be carried out with flat jet nozzles. Included 'an optimal cooling with the best possible supported strand surface can be achieved.

The guide plates can also be connected to the mold, so that they co-oscillate with it. As a result, the otherwise between the mold remains and guide plate constantly in its! width changing gap constant, whereby the risk of breakthrough is also reduced.

Claims (16)

PATENT CLAIMS; 1. Method for cooling by means of spray nozzles and guiding a strand in the secondary cooling zone of a continuous casting plant, with the strand passing through on opposite sides Guide elements resting against the strand surfaces and passed between the Guide elements is cooled, characterized in that the moving strand in the longitudinal and transverse directions alternately by spraying onto unsupported surfaces Water is applied, cooled and then guided on supported surfaces, wherein the areas of the supported surfaces are kept essentially free of water. 2. The method according to claim 1, characterized in that the sprayed Water away from the strand backwards outside of the following in the strand running direction Spray fan is derived. 3. The method according to claim 1 or 2, characterized in that the strand is acted upon by cooling water from two adjacent spray nozzles, with the impacted surfaces merge almost immediately into one another and together roughly correspond to the unsupported area. 4. The method according to any one of claims 1 to 3, characterized in that that by choosing the spray angle of the nozzle and / or its setting, the above and guides located on the side of the nozzle are cooled by spray water, and a small area near the lower guide is not directly exposed to the spray water will. 5. Device for performing the method according to one of the claims. 1 to 4, characterized in that the guide elements consist of grid-like plates (3,3 ', 4,4') associated with the strand surface and corresponding to its shape There are guide surfaces (10), the plates have recesses between the guide surfaces (11) in the longitudinal direction (18) and transverse direction (19), - the unsupported Corresponding surfaces (16) of the strand, and spray nozzles (8) arranged in the recesses are, the cooling water through the recesses of the plate (3,3 ', 4,4') on the strand surface spray. 6. The device according to claim 5, characterized in that the Plate (3,3 ', 4,4') at least two lying one below the other in the strand running direction Has rows (12, 13) of recesses that are mutually interconnected by a web-shaped Guide surface (10) are separated. 7. Apparatus according to claim 6, characterized in that the 'recesses of these rows (12,13! are arranged offset from one another. 8. Device according to one of claims 5 to 7, characterized in that that the size of the strand surface acted upon by the spray fan is essentially corresponds to the unsupported surface (16). 9. Device according to one of claims 5 to 8, characterized in that that the lower boundary surface (21) of the recess (11) at an angle (22) is inclined backwards and downwards. 10. The device according to claim 9, characterized in that the Angle (22) is between 100 and 250. 11. The device according to claim 9 or 10, characterized in that that the inclined boundary surface (21) has a drainage opening (23) for accumulated Has water. 12. Device according to one of claims 9 to 11, characterized in that that the rear edge of the lower boundary surface (21) and / or the drainage opening (23) is set back over the spray nozzle below. 13. Device according to one of claims 5 to 12, characterized in that that the grid-like guide surfaces (10) are arranged obliquely to the strand running direction are. 14. Device according to one of claims 5 to 13, characterized in that that the grid-like plates (3,3 ', 4,4') across the strand width in partial plates (30, 30 ') are subdivided and fastened interchangeably on a support frame (31). 15. Device according to one of claims 5 to 14, characterized in that that the grid-like plates (3,3 ', 4,4') are made of wear-resistant cast iron. 16. Device according to one of claims 5 to 14, characterized in that that the distance (29) from opposing plates (3,3 ', 4,4') is adjustable.