EP0812638A1 - Adjustable continuous casting mould - Google Patents

Abstract

The adjustable continuous billet casting mould consists of two stationary side walls and two end walls (10), with at least one end wall movable relative to the other. The end walls are provided with a coolant chamber (80) and several channels (88) for applying coolant to the billet material. The mould has an additional coolant chamber (90) and channels (94) in its end walls (10). The channels (94) are arranged so that coolant from them is applied to the billet material after coolant from the channels (88). Also claimed are a method for operating such a mould and an application of the mould for production of light-metal (in particular, aluminium and magnesium alloy) billets.

Description

The invention relates to an adjustable continuous casting mold for the production of continuous cast ingots of different dimensions, comprising a mold frame with a pair of opposite stationary side walls and a pair of opposite end walls, at least one end wall being slidably arranged, and each side and end wall having a first coolant chamber and a plurality with the first coolant chamber communicating with first coolant channels for applying coolant to the continuous casting material. The invention further relates to a method for carrying out the continuous casting process with the mold according to the invention.

Continuous casting molds are used to pour liquid metal from a ladle or the like into a mold, it being possible to produce workpieces with a full or hollow cross section. Such continuous casting devices for the production of ingots or bolts as primary material for their further processing by, for example, extrusion or rolling consist of a water-cooled mold, i.e. a mold which is usually open at the top, with parallel walls and an initially tightly closing but lowerable bottom, the mold walls usually being hollow and being cooled with water.

In continuous casting, molten metal is poured at a predetermined speed onto a start-up floor that initially closes tightly with the mold frame. The mold frame forms the vessel wall for the melt and must therefore be leakproof over its entire circumference. The mold bottom is then lowered during the continuous casting, and at the same time so much metal melt is always refilled into the mold that the level of the melt in the mold remains constant. The mold bottom is therefore lowered at a speed adapted to the pouring rate.

The mold frame serves on the one hand for shaping and on the other hand for heat dissipation from the melt. If the metal melt is poured into the mold, this melt solidifies rapidly on the walls and bottom of the mold, so that at least the outermost edge zone of the melt solidifies within the mold frame. By applying a coolant to the billet emerging from the mold, such as spraying the strand with water, the area near the surface of the strand emerging from the mold is further rapidly solidified, so that a bowl whose content is still liquid is formed.

For the continuous casting of metal billets and other such castings, special molds are usually used for each billet width. The production of Continuous casting molds are - especially due to their narrow dimensional tolerances - complex and costly. The numerous different cast ingot formats also entail the uneconomical need to keep a correspondingly large number of molds in stock.

In order to partially remedy this disadvantage, a mold made of a closed ring with parallel side and end walls, in which at least one end wall is adjustable within the closed ring, was proposed in German Auslegeschrift 1,059,626 for the production of castings with an elongated cross section. The adjustable walls are set to the desired bar cross-section in advance of the continuous casting process, the adjustable walls being fixed to the remaining mold frame by means of screws.

In the case of the mold designed according to DE-OS 1 059 626, however, the mold base must always be adapted to the new bar cross section. In addition, the adjustment of the mold frame to the respective bar cross-sections requires a lot of time and usually leads to a longer interruption in the production line, which has an unfavorable effect on the production time and the production costs if only a few castings of a certain width are required.

In order to remedy this disadvantage, FR Application No. 83 15766, which is disclosed under No. 2 552 692, describes a mold with a mold cross section that can be adjusted during the continuous casting process, this being accomplished by computer-controlled adjustment of the inclination of an adjustable end wall. However, the computing effort for such a bar cross-section control is large, which requires the use of powerful computers.

In the case of continuous casting molds, the fixed edge zone of the ingot emerging from the mold in the mold area must withstand the total pressure of the continuous casting material above it at each location, the total pressure being the hydrostatic pressure of the continuous casting material melt and the pressure of the over your lying solidified casting material results. While in the case of stationary, vertical mold walls, the total pressure directed to the surface of the edge zone depends only on the hydrostatic pressure of the continuous casting material melt, the total pressure in the case of ingots emerging from the mold, which have a non-perpendicular edge zone, in addition to the hydrostatic pressure due to the perpendicular to the edge zone acting component of the solidified continuous cast material lying above it. Thus, in the case of molds, the walls of which are adjustable during the continuous casting process, the Rate of adaptation of the mold cross-section to the desired ingot cross-section, in particular in the case of a cross-sectional enlargement, depends on the continuous casting material and on the thickness of the solidified edge zone. Since in the case of molds with a variable mold cross-section, to avoid material waste, the continuous casting process is preferably started with a starting cross-section which is smaller than the desired bar cross-section and which is then gradually adapted to the desired bar cross-section, resulting from the thin ingot edge zone formed within the mold usually a very low, maximum adaptation rate of the mold cross-section. This has a correspondingly negative effect, particularly in the case of a strongly changing bar cross section and leads to a large loss of material, since the bar part with a variable cross section is usually unsuitable for further processing.

The inventor has now set himself the task of creating an adjustable mold, which allows a quick bar cross-section adjustment and thus the very cost-effective production of rolled or pressed bars with different cross-sectional dimensions with one and the same mold.

According to the invention, this is achieved in that the displaceable end walls have a second coolant chamber, and also a plurality of second coolant channels connected to the second coolant chamber for further application of coolant to the continuous casting material, the second coolant channels being arranged in such a way that the coolant emerging from the second coolant channels Seen in the flow direction of the continuous casting material, after the coolant emerging from the first coolant channels strikes the continuous casting material.

Which walls of the mold frame are referred to as end walls and which are referred to as side walls is in itself irrelevant to the present invention. It is essential to the invention that the mold frame contains at least one movable wall designed according to the invention.

The first coolant chamber fulfills two functions: on the one hand it serves to cool the shaping part of the mold frame and thus for direct heat dissipation from the continuous casting material and on the other hand as a coolant supply for the coolant channels, the coolant being directed onto the surface of the continuous casting material emerging from the mold, thereby leading to the edge zone of the continuous cast ingot is cooled further. In order to ensure the highest possible heat dissipation, the first function of the first coolant chamber on the one hand requires a thin wall thickness between the coolant chamber and the inner wall of the mold frame and, on the other hand, good thermal conductivity of the wall material.

The second coolant chamber essentially serves only to supply coolant to the second coolant channels. The coolant flowing through the second coolant channels and striking the continuous casting material in the continuous casting material leads to a faster solidification in the region of the displaceable end walls or to the formation of a thicker, consolidated edge zone. The resulting thicker edge zone resists a higher total pressure of the continuous casting material lying above it, so that the continuous casting mold designed according to the invention allows the mold cross section to be adapted more quickly to the desired ingot cross section; this is particularly the case with a cross section of the mold frame that increases during the continuous casting process.

The additional coolant applied to the continuous casting material by the second coolant channels is only necessary on the movable mold walls, since the primary cooling of the continuous casting material by the first coolant chamber and the first coolant channels creates a sufficiently thick edge zone in the area of the stationary, vertical mold walls to accommodate the hydrostatic pressure of the vertical Resist continuous casting material column lying above this edge zone. Accordingly, during the continuous casting process, the secondary coolant supply through the second coolant channels can be stopped, for example, after the desired ingot cross-section has been reached, so that the displaceable end walls of the mold according to the invention preferably have a valve for interrupting the coolant supply to the second coolant chamber or to the second coolant channels.

With the mold according to the invention, the mold cross section can be adapted to the required ingot cross section by a purely translational displacement of the displaceable end walls, so that no complex adjustment of the inclination angle of the end walls is necessary for setting the ingot cross section.

The ingots produced by continuous casting usually have somewhat concave side faces. This concavity of the ingot side surfaces is due to a shrinkage process taking place during the cooling of the melt and occurs in particular on the flat sides of long-shaped, rectangular rolling ingots. The concave curvature of the ingot sidewalls resulting from the shrinking process depends, among other things, on their format, alloy and the casting speed. Typical values for the feed are 5 to 10 mm per side for rolled bars of the format 300 x 1000 mm made of a magnesium-containing aluminum alloy and at a casting speed of 5 to 8 cm per minute. Such deviations from the planarity of the surface are undesirable insofar as they occur during milling lead to an increase in waste and cause difficulties with the rolling of the bars when rolling.

In order to avoid the formation of concave side surfaces, the inner surfaces of the continuous casting mold are curved outwards in accordance with the degree of shrinkage. As a result of these measures, the molten metal leaves the mold with the side surfaces curved outwards, which then become flat as a result of the shrinkage.

According to the invention, the first and second coolant channels are designed such that the coolant emerging from the second coolant channels, viewed in the flow direction of the continuous casting material, strikes the continuous casting material after the coolant emerging from the first coolant channels. The first coolant channels are preferably designed in such a way that their longitudinal axes form an acute angle of 20 to 40 ° with the central axis of the mold cavity delimited by the mold frame. The central axis of the mold cavity is understood to mean the central axis of the mold cavity which is parallel to the flow direction of the continuous casting material. The longitudinal axes of the second coolant channels preferably form an angle of 60 to 85 ° with the central axis of the mold cavity.

The number of first coolant channels depends, among other things. on the size of the ingots to be produced, the continuous casting speed and the continuous casting material. The side walls preferably contain 8 to 30 and the fixed end wall 5 to 25 first coolant channels.

The openings of the first coolant channels directed against the mold cavity are preferably all in the same cross-sectional plane of the mold. In addition, the coolant channels are preferably arranged in such a way that the coolant is applied uniformly over the entire cross-section of the ingot.

The number of second coolant channels depends, among other things. on the length of the movable end wall or on the bar cross-section, on the continuous casting material and the speed at which the mold cross-section adapts to the desired bar cross-section. The number of second coolant channels per displaceable end wall is preferably between 8 and 30.

The openings of the second coolant channels directed against the mold cavity are preferably all located on the same cross-sectional plane of the mold and are preferably arranged in such a way that the coolant is applied uniformly to the side faces of the ingot adjacent to the displaceable end walls.

The continuous casting mold according to the invention preferably contains a lubricant distribution element for the supply of lubricant to at least the entire shaping part of the inner wall which is directly exposed to the continuous casting material, in the region of the inner wall of the mold frame which is directed toward the continuous casting material and which flows in with respect to the continuous casting material. It is essential that between the continuous casting material and the entire part of the mold frame that is mechanically directly exposed to the continuous casting material, i.e. a lubricant or lubricant is introduced into the shaping inner wall of the end and side walls directed against the mold cavity.

The lubricant distribution element can be a closed, ring-shaped element, or can consist of a plurality of sub-elements which are arranged at intervals on the same mold cross-sectional plane. A closed ring-shaped lubricant distribution element expediently consists of four elongated partial elements lying in the same cross-sectional plane of the mold, each end and side wall containing such a partial element. A lubricant distribution element, which consists of a plurality of sub-elements arranged at intervals from one another, expediently contains all of these sub-elements in the same cross-sectional plane of the mold, the arrangement and / or configuration of the sub-elements preferably being such that the lubricant or lubricant is evenly dispensed the entire shaping inner wall of the mold frame takes place.

The supply of coolant and lubricant to the displaceable end walls preferably takes place via flexible hose lines, which are designed in length in such a way that they do not restrict the movement of the end walls.

In a preferred embodiment of the mold according to the invention, the end and side walls have a modular structure, each end and side wall having a central part containing the first coolant chamber and the first coolant channels, and two connecting profiles adjoining the central part on both sides in the longitudinal direction of the mold, and the inner walls of the middle parts directed against the continuous casting material form the shaping surface of the mold. The longitudinal direction of the mold is an axis that is parallel to the direction of flow of the continuous casting material. The front connection profile seen in the flow direction of the continuous casting material is referred to below as the first connection profile, and the connection profile following the central part, which is seen in the flow direction of the continuous casting material, is referred to as the second connection profile. During the continuous casting process, the continuous casting material thus passes through the one enclosed by the first connection profiles Part, then the part enclosed by the middle parts and finally the part of the mold cavity enclosed by the second connection profiles.

The middle part very preferably has an essentially U-shaped longitudinal section, so that by joining the middle part with the second connection profile, as seen in the direction of flow of the continuous casting material, a cavity is formed as the first coolant chamber.

The inner walls of the end and side walls directed against the mold cavity can, as a whole, enclose a cylindrical cavity, expediently a cavity with a square cross section. However, the individual inner walls do not have to describe a one-piece surface lying parallel to the longitudinal axis of the mold. Rather, the mold cavity can be formed by a plurality of mold partial cavities arranged sequentially one after the other.

The cavity enclosed by the connection profiles of the front and side walls has, for example, a larger cross section than the cavity formed by the central parts of the front and side walls. In such a mold cavity, the cavity formed by the middle parts has a smaller cross-section and thus, due to the cooling effect of the inner wall, brings about the shaping of the continuous casting material.

The shaping of the continuous casting material is preferably effected by the middle parts of the end and side walls. The shaping inner wall of each central part is thus preferably projecting over the corresponding inner wall of the second connection profile. The protruding inner wall of the central part is understood to mean the position in the direction of the central axis of the mold cavity. The shaping inner wall of each central part is furthermore preferably protruding from the corresponding wall of the first connection profile.

In a further preferred embodiment of the continuous casting mold according to the invention, the second connection profiles of the displaceable end walls, as seen in the flow direction of the continuous casting material, each have the second coolant chamber and the second coolant channels.

The front and side walls of the mold according to the invention can be made of any material which gives the mold sufficient mechanical and thermal strength and sufficient dimensional stability. In this case, with a modular structure Chill molds The individual mold elements consist of the same or different materials. The end and side walls or their partial elements expediently consist of metal.

According to the present invention, the bar width can be set by program-controlled regulation of the mold opening or the end wall distance, this being done by positioning either only one end wall or, for example, by shifting both end walls in opposite directions. Usually, however, to adjust the desired bar width by regulating the distance between two opposite end walls, the displacement of only one end wall is sufficient. The following description therefore starts from the setting of a single end wall per mold, although for certain mold designs a symmetrical and simultaneous setting of both end walls compared to the center of the mold can be advantageous. However, the present subject matter of the invention comprises the regulation of the mold opening by adjusting only one end wall as well as by simultaneously adjusting both opposite end walls.

With a mold according to the invention, the end wall distance can advantageously be varied in a range from 10 to 1000 mm and in particular from 100 to 500 mm.

The movable end walls can be driven, for example, by mechanical, hydraulic, pneumatic or electromagnetic means. The positioning and fixing of each displaceable end wall expediently takes place via at least one axle shaft, for example lying parallel to the direction of movement of the end wall, which can be designed as a solid or hollow profile or as a piston-shaped element.

Each movable end wall is positioned, for example, via at least one axle shaft according to a predetermined program. When using only one axle shaft per end wall, the axle shaft is expediently fixed in the center of the end wall. When using several axle shafts per end wall, a synchronous movement of all axis shafts involved in the end wall movement must be ensured.

The thrust required for positioning and fixing the end wall is expediently carried out by a drive shaft driven by a motor, wherein the rotary movement of the drive shaft can be converted into an axial thrust in the direction of the axle shaft by means of a gear. If several axle shafts are used for positioning the end wall, or several continuous casting molds according to the invention are used in parallel operated, the axis shafts involved are preferably driven by one and the same drive shaft to ensure synchronous movement.

As a transmission, for example, traction, articulated, screw or wheel gear come into question. Gearwheels in the form of single-stage or multi-stage gearwheels are preferably used. These allow slip-free transmission of the rotary motion of the drive shaft to the axle shaft (s) in a defined gear ratio.

For example, cylindrical spur gears, bevel or worm gears are suitable as gear drives. The cylindrical gears can be straight, oblique, arrow-shaped (arrow gears), or helical (screw gears), as well as internally or externally toothed. Bevel gears have a conical circumferential surface with straight, helical or curved teeth.

The displacement of the end wall required for the setting of the mold opening can take place, for example, by means of an axle shaft which is fixedly connected to the end wall, the other end of the axle shaft being designed as a rack into which - optionally via a transmission gear - a gearwheel which is firmly connected to the drive shaft intervenes.

The axle shaft (s) can be fixed to the end wall, for example, by screwing, jamming, riveting or welding. However, detachable connections are preferably used - for the purpose of easier interchangeability of mold elements subject to wear.

Another possibility for the transmission of the rotational movement of the drive shaft into an axial displacement of the end wall lies, for example, in the transmission of the rotational movement of the drive shaft to the axle shaft / n by torque transmission by means of a gear, such as a gear transmission, the drive and axle shafts each being fixed have gear connected to their axes. The rotary movement of the axle shaft (s) can then, for example, by means of a spindle gear, i.e. a threaded hole in the end wall or in a molding of the end wall, into which the axle shaft (spindle), which is threaded on its periphery, engages, is converted into an axial movement of the end wall.

The use of the mold described in the present invention for the production of continuous cast ingots of different dimensions with a mold base having fixed dimensions has an advantage over the conventional molds with usually means Screws or the like on the side walls in question have a large manufacturing time and cost advantage.

Compared to the adjustable continuous casting molds known from the prior art, in which the mold cross section has to be carried out prior to the continuous casting process, the mold according to the invention permits the setting of the ingot cross section during the continuous casting process, so that there is no interruption in operation in the production line for manual settings of the mold cross section . In particular, this advantage has an effect in the case of a plurality of continuous casting molds operating in parallel, since all mold openings can be adjusted jointly or individually, for example by means of one and the same drive shaft or by means of several drive shafts. In addition, the mold designed in accordance with the present invention enables the bar dimensions to be infinitely adjusted, while in the known molds with end wall settings to be made beforehand to the continuous casting process, usually only between 3 and 5 positions are available for fixing the end walls.

Compared to a mold with a mold cross-section that can be changed by the angle of inclination of the end walls, the mold according to the invention has a significantly higher adaptation rate to the required bar cross-section; in addition, the translational displacement of the end wall allows the bar cross-section adjustment to be carried out more easily and the bar cross-section setting to be more accurate.

The continuous casting mold according to the invention is suitable for the continuous production of rolled or pressed bars made of light metal or light metal alloys and in particular for the continuous production of rolled or pressed bars made of aluminum or magnesium alloys.

The invention also relates to a method for the continuous casting of metal bars by means of a continuous casting mold according to the present invention, the lowerable mold base having fixed dimensions, and the positioning of each displaceable end wall being carried out by a drive controlled by a control unit.

According to the invention, the distance between the end walls is initially set such that at the beginning of the continuous casting process the cross section of the mold cavity corresponds to the surface of the lowerable mold bottom available for receiving the continuous casting material, and the distance of the end walls in the course of the continuous casting process is controlled in a program-controlled manner by means of the drive controlled by the control unit in cooperation with the lowering of the mold bottom in such a way that the cross section of the mold cavity is continuously or step-wise adjusted to the dimensions of the desired continuous casting ingot.

The regulation of the end wall distance effected by the control unit is preferably controlled in a time-dependent manner in accordance with a fixed program, a so-called setpoint curve.

The position of each displaceable end wall can also be determined at any time by means of a position measuring device, so that the positioning of the displaceable end walls caused by the control unit and the drive according to the difference between the measured time-dependent position of the relevant end walls and a time-dependent position defined in a predetermined program Position value happens.

The cross section of the melt column is expediently smaller at the beginning of the process according to the invention than the cross section of the ingot to be produced. In the course of the lowering process of the mold bottom, the mold opening can then be changed step by step or continuously in such a way that the cooled ingot has the desired cross-section, apart from the initial part caused by the cross-sectional regulation. The initial part of the ingot formed at the beginning of the continuous casting process is, for example, essentially conical, or has, for example, a plurality of conical parts which follow one another in steps. The simple or step-shaped conical starting parts of the ingot can, for example, have the shape of a truncated pyramid or a truncated cone.

The shape of the conical billet parts results essentially from the speed of the change in the distance of the end walls in cooperation with the speed of the lowering of the mold bottom. The process control is preferably carried out in such a way that the surface normal of the conical ingot parts formed includes a minimum acute angle of 25 ° with the longitudinal axis of the ingot, in particular an angle between 30 and 80 °.

In order to minimize the material waste during the further processing of the continuous cast ingot, the maximum lowering depth of the mold base until the constant and required for the desired ingot cross-sectional dimensions of the continuous casting material cross-section, i.e. the height of the pyramid-shaped or truncated cone-shaped part, is expediently less than 50 cm and in particular less than 30 cm.

Compared to the known continuous casting process, the method according to the invention enables the continuously adjustable mold opening to produce continuous casting bars with any dimensions chosen according to customer requirements, the initial part usually not usable for the further processing of the continuous casting bars compared to that used in the manufacture of bars from the Known prior art, controllable molds results, turns out to be much less.

With regard to the continuous casting mold according to the invention, further advantages, features and details of the invention result from the following exemplary figures.

FIG. 1 shows a longitudinal section through a displaceable end wall of an adjustable continuous casting mold according to the present invention.

FIG. 2 shows a top view of a system of adjustable continuous casting molds.

The longitudinal section shown in FIG. 1 through a displaceable end wall 10 shows an example of its modular structure. The end wall 10 consists of a central part 70, as well as two connecting profiles 72, 74 adjoining the central part 70 on both sides in the mold longitudinal direction. The central part 70 has a U-shaped longitudinal section. After the second connection profile 74, as seen in the direction of flow of the continuous casting material, has been fixed to the central part 70, a first coolant chamber 80 is formed in the displaceable end wall 10. The end wall 10 has a first coolant supply 84 for supplying coolant to the first coolant chamber 80.

To apply coolant to the continuous casting ingot, first coolant channels 88, which are connected to the coolant chamber 80, are embedded in the end wall 10 in such a way that the coolant strikes the continuous casting material at an acute angle of approximately 30 ° to the central axis of the mold cavity 12. The angle information in the present text is always based on a full circle of 360 °. In order to ensure sufficient coolant entry into the first coolant channels 88, the first coolant chamber 80 each has a coolant channel recess 86 at the points of entry of the coolant into the first coolant channels 88.

The first coolant chamber 80 shown in FIG. 1 contains, as a fluid dynamic calming element for the coolant, a partition wall 82 provided with through openings (not shown). The partition wall 82 is at one end with a fastening compound 83, for example from a putty. The other end of the partition is in a groove 75 embedded in the second connection profile 74.

The longitudinal section of an end wall 10 shown in FIG. 1 also shows, in the area of the inner wall 71 of the central part 70 directed against the mold cavity 12, a lubricant distribution element 76 for supplying lubricant to the inflow area of the central part 70. The supply of the lubricant distribution element 76 with lubricant or lubricant takes place via the lubricant feed 78. The lubricant distribution element 76 - as seen in the direction of flow of the continuous casting material - is partially covered on the inflow-side region by the first connection profile 72.

The second connection profile 74, seen in the direction of flow of the continuous casting material, has the second coolant chamber 90 and the second coolant channels 94, which are essential to the invention, for the further application of coolant to the ingot. The longitudinal section of the displaceable end wall 10 also shows the second coolant supply 92 for supplying the second coolant chamber 90 with coolant. The second coolant supply to the ingot 54, which is necessary for the displaceable end walls 10, takes place by means of the coolant flowing through the second coolant channels 94, the second coolant channels 94 being connected to the second coolant chamber 90 and being supplied with coolant by the latter.

In a preferred embodiment of the mold according to the invention, the structure of the side walls 20, as well as the end wall rigidly fixed with the side walls 20, corresponds to that - apart from the second coolant channels 94, the second coolant chamber 90 and the second coolant supply 92 contained in the second connection profile 74 the sliding end wall 10.

FIG. 2 shows a system of adjustable continuous casting molds, only two corresponding molds 60 being shown by way of example for the sake of clarity. Each mold 60 has a mold frame 62, containing a pair of opposite side walls 20 and a pair of opposite movable end walls 10, the cavity enclosed by all four walls 10, 20 forming the mold cavity 12. The inner wall 28 of the mold frame 62 delimiting the mold cavity 12 serves to hold the continuous casting material. The inner wall 28 contains cooling chambers 80, 90, as a result of which the continuous casting material is cooled at least in the edge zone, so that it is solidified at least in this edge zone and emerges from the mold in the form of an ingot 54 (shown in broken lines).

The side walls 20 of each mold 60 are rigidly connected to one another by profiles 25 at a predetermined distance. The end walls 10 are slidably mounted by means of sliding shoes 15 which have recesses into which guide rails (not shown) fastened on the surface 21 of the side walls 20 engage and are driven by axle shafts 30. The axle shafts are connected via a gear 32 to the drive shaft 34 which is common to a series of continuous casting molds 60 working in parallel. The drive shaft 34 is driven by a motor 40, the motor being controlled by means of a control unit 44 in accordance with, for example, a predetermined program in accordance with the position of the end wall 10 determined by the position measuring device 50. The current position of each movable end wall 10 is transmitted to the control unit 44 by means of a measurement signal line 52. The control signals from the control unit 44 required for the drive 40 are transmitted by means of a control cable 46.

Claims (14)

Adjustable continuous casting mold (60) for the production of continuous cast ingots (54) of different dimensions, comprising a mold frame (62) with a pair of opposite stationary side walls (20) and a pair of opposite end walls (10), at least one end wall (10) being slidably arranged, and each side (20) and end wall (10) has a first coolant chamber (80) and a plurality of first coolant channels (88) connected to the first coolant chamber (80) for applying coolant to the continuous casting material,
characterized in that
the displaceable end walls (10) have a second coolant chamber (90) as well as a plurality of second coolant channels (94) connected to the second coolant chamber (90) for the further application of coolant to the continuous casting material, the second coolant channels (94) being arranged in this way, that the coolant emerging from the second coolant channels (94), viewed in the flow direction of the continuous casting material, strikes the continuous casting material after the coolant emerging from the first coolant channels (88). Continuous casting mold according to claim 1, characterized in that the longitudinal axes of the first coolant channels (88) form an acute angle of 20 to 40 ° with the central axis of the mold cavity (12) delimited by the mold frame (62). Continuous casting mold according to claim 1 or 2, characterized in that the longitudinal axes of the second coolant channels (94) form an angle of 60 to 85 ° with the central axis of the mold cavity (12) delimited by the mold frame (62). Continuous casting mold according to one of claims 1 to 3, characterized in that the mold (60) has a lubricant distribution element (76) for the supply of on the area of the inner wall (28) of the mold frame (62) directed towards the mold cavity (12) which is directed towards the mold material Contains lubricant on at least the entire shaping part (71) of the inner wall (28) that is directly exposed to the continuous casting material. Continuous casting mold according to one of claims 1 to 4, characterized in that the end walls (10) and side walls (20) are of modular construction, the end walls (10) and side walls (20) each being the first coolant chamber (80) and the the first coolant channels (88) containing the central part (70), and two connecting profiles (72, 74) adjoining the central part (70) on both sides in the mold longitudinal direction, and the inner walls (71) of the central parts (70) directed against the continuous casting material Form the shaping surface of the mold (60). Continuous casting mold according to claim 5, characterized in that the central part (70) has a substantially U-shaped longitudinal section such that a cavity is formed as the first coolant chamber (80) by joining the central part (70) to the second connection profile (74) . Continuous casting mold according to claim 5 or 6, characterized in that the shaping inner wall (71) projects from the side of the second connection profile (74) directed against the mold cavity (12). Continuous casting mold according to one of claims 5 to 7, characterized in that the shaping inner wall (71) protrudes from the side of the first connection profile (72) directed against the mold cavity (12). Continuous casting mold according to one of claims 5 to 8, characterized in that the second connection profile (74) of the displaceable end walls (10) contains the second coolant chamber (90) and the second coolant channels (94) Use of the continuous casting mold according to one of claims 1 to 9 for the continuous production of rolled or pressed bars from light metal or light metal alloys, in particular from aluminum or magnesium alloys. Method for the continuous casting of metal bars by means of a continuous casting mold according to one of claims 1 to 9, wherein the lowerable mold base has fixed dimensions, and the positioning of each movable end wall (10) is carried out by a drive (40) controlled by a control unit (44)
characterized in that
the distance between the end walls (10) is initially set such that at the beginning of the continuous casting process the cross section of the mold cavity (12) corresponds to the surface of the lowerable mold bottom available for receiving the continuous casting material, and the distance between the end walls (10) in the course of the The continuous casting process is controlled in a program-controlled manner by means of the drive (40) controlled by the control unit (44) in cooperation with the lowering of the mold bottom in such a way that the cross section of the mold cavity (12) is adjusted continuously or step by step to the dimensions of the desired continuous casting ingot (54). A method according to claim 11, characterized in that the control unit (44) operates according to a fixed, time-dependent program. The method according to claim 11, wherein the position of each displaceable end wall (10) can be determined at any time by means of a position measuring device (50), characterized in that the positioning of the displaceable end walls (10) brought about by the control unit (44) and the drive (40) ) according to the difference between the measured, time-dependent position of the relevant end walls (10) and a time-dependent position value defined in a predetermined program. Method according to one of claims 11 to 13, characterized in that the length of the pyramid-shaped or truncated cone-shaped bar part brought about by the regulation of the ingot cross section made at the beginning of the continuous casting process is less than 50 cm and in particular less than 30 cm.

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