AT526905B1 - continuous cooling device - Google Patents

Abstract

The invention relates to a belt floating cooler for cooling a metal strip (2), with at least one belt cooler (7) which has a plurality of lower discharge elements (9) for a gaseous fluid distributed along a direction of travel (8) of the metal strip (2) and a plurality of upper discharge elements (10) for a gaseous fluid distributed along the direction of travel (8) of the metal strip (2), and with a plurality of liquid cooling units (12) with which the metal strip (2) can be supplied with a cooling liquid, wherein at least one transport device (14) with at least one transport element (15) for transporting the metal strip (2) is arranged between the upper and lower discharge elements (9, 10).

Description

Description

[0001] The invention relates to a belt suspension cooler for cooling a metal strip, with at least one belt cooler which has a plurality of lower discharge elements for a gaseous fluid distributed along a direction of travel of the strip and a plurality of upper discharge elements for a gaseous fluid distributed along the direction of travel of the strip, and with a plurality of liquid cooling units with which the metal strip can be supplied with a cooling liquid.

[0002] The invention further relates to a plant for the heat treatment of a metal strip with at least one strip casting device in which the metal strip is produced from a melt, and optionally with at least one heat treatment device in which the metal strip is heated or through which the metal strip passes in a heated state, and at least one strip flotation cooler.

[0003] In addition, the invention relates to a method for cooling a metal strip in a belt flotation cooler with at least one belt cooler which has a plurality of lower discharge elements for a gaseous fluid distributed along a direction of travel of the metal strip and a plurality of upper discharge elements for a gaseous fluid distributed along the direction of travel of the strip, and which has a plurality of liquid cooling units with which the metal strip can be supplied with a cooling liquid, wherein the metal strip is exposed to a gaseous fluid which is directed from the upper and lower discharge elements in the direction of the metal strip, and to a cooling liquid which is applied to the metal strip emerging from the liquid cooling units.

[0004] Continuous cooling devices of the design mentioned at the beginning are already known from the prior art. For example, DE 10 2016 102 093 B3 describes a continuous cooling device for cooling a metal strip, with at least one strip floating cooler, which has several upper nozzles distributed along the direction of strip travel and several lower nozzles distributed along the direction of strip travel, wherein the metal strip can be transported in a floating manner between the upper nozzles and the lower nozzles and both the top and bottom of the strip can be supplied with cooling air, and with several water cooling units, with which the metal strip can be supplied with cooling water, and which are integrated into the strip floating cooler by arranging at least one water cooling unit in several intermediate areas between each two lower nozzles or upper nozzles arranged directly one behind the other in the direction of strip travel.

[0005] WO 2018/162474 A1 describes a strip levitation system for levitating a strip-shaped material, which has a first nozzle system and a second nozzle system, wherein the first nozzle system is arranged relative to the second nozzle system such that the strip-shaped material can be guided between the first nozzle system and the second nozzle system. The nozzle systems comprise a nozzle body which has a front edge region along a conveying direction of the strip-shaped material and a rear edge region lying opposite it, a front gas nozzle arrangement which is arranged on the front edge region such that a front gas jet can flow in the direction of the strip running plane to form a floating nozzle field for the strip-shaped material, a rear gas nozzle arrangement which is arranged on the rear edge region such that a rear gas jet can flow in the direction of the strip running plane to form the floating nozzle field for the strip-shaped material, a nozzle arrangement which is arranged in front of the front gas nozzle arrangement and/or behind the rear gas nozzle arrangement in the conveying direction, wherein the nozzle arrangement is set up such that a liquid fluid in a fluid jet can flow into the floating nozzle field in the direction of the strip running plane to temper the strip-shaped material.

[0006] From DE 196 49 073 A1 a device for cooling extruded profiles is known with air slot nozzles arranged above and below the extruded profile moving on a discharge track and running transversely to the direction of profile movement, in which pipes equipped with water nozzles running in the direction of profile movement are integrated into the air nozzle arrangement.

are grated and these pipes are arranged above, below and to the side of the extruded profile in such a way that the impact fields of the individual water nozzles complement each other by superimposing them to ensure a uniform water impact on the profile, so that cooling can be carried out either with air only or with water only.

[0007] From EP 0 098 492 A2 a plant is known for accelerated cooling of a railway rail which is moved longitudinally through the plant at an initial temperature above the austenite to ferrite transformation temperature. The plant comprises means for subjecting the head portion of the rail to intermittent, forced cooling such that the near surface region of the rail remains safely above the martensite transformation temperature, the means including a series of cooling heads spaced longitudinally from one another in intermittent cooling zones of selected lengths, the cooling heads being operable to supply a liquid coolant to the rail to achieve a relatively high cooling rate of the rail as it passes through the individual cooling heads, and the zones of intermittent cooling reducing the cooling rate of the rail to a relatively low value as it passes through the individual such zones. The system further comprises means for moving the rail in the longitudinal direction through the series of cooling heads and zones of intermittent cooling such that the head of the rail is exposed to the liquid cooling medium, and a control device for terminating the use of the liquid cooling medium when the head of the rail has reached a predetermined cooling holding temperature.

[0008] CN 105567921 B describes a device for cooling aluminium profiles, which is divided into several sections, whereby, depending on the section, the aluminium profile is cooled on both sides with water and/or air.

[0009] JP 2008-073766 A describes a device for cooling a steel strip on a roller conveyor, wherein the top of the strip has several cooling sections in which water is applied to the strip via cooling nozzles. Cooling water is also applied to the strip from below via nozzles between the rollers. Air nozzles can be used to remove cooling water from the surface of the strip.

[0010] JP 2002-316205 A describes a device for cooling a steel strip that is guided over a large number of rollers. Between the rollers, opposing cooling sections are arranged above and below, through which cooling water is sprayed onto the strip. Cooling air can also be sprayed from above.

[0011] The present invention is based on the object of improving the handling of a metal strip in a warm or hot state.

[0012] The object of the invention is achieved with the initially mentioned continuous cooling, in which at least one transport device with at least one transport element for temporarily transporting the metal strip is arranged between the upper and lower discharge elements.

[0013] Furthermore, the object of the invention is achieved with the system mentioned at the outset, which has the belt flotation cooler according to the invention.

[0014] In addition, the object is achieved with the method mentioned at the outset, according to which it is provided that a free initial section of the metal strip is placed on a transport element of a transport device which is arranged between the upper and lower discharge elements and is conveyed through the belt suspension cooler with the transport element, that with or after leaving the free initial section the conveying quantity of gaseous fluid is increased so that the metal strip is brought into a floating state within the belt suspension cooler.

[0015] The advantage here is that the transport device can improve the strip entry into the strip floatation cooler. In particular, it is possible to achieve a stable state in the strip and the process more safely and quickly, since the floatation of the metal strip is only activated when the free end section has already left the strip floatation cooler. Due to the contact-bound transport of the free initial section of the

metal strip, it is possible to reduce the tensile stress applied to this section in the warm or hot state, thus reducing its influence on the metal strip.

[0016] According to a variant embodiment of the invention, the transport device can have several transport modules that are arranged one behind the other in the direction of travel of the belt. The modular structure of the transport device makes it easier to adapt to different belt flotation coolers.

[0017] According to a further embodiment of the invention, the transport modules can each have at least one transport element, which can improve the ability of the transport system and thus also the belt suspension cooler to adapt to the progress of the treatment of the metal strip. In particular, it is easier to switch to the suspended transport of the metal strip at an early stage in some areas of the belt suspension cooler. In addition, it is possible to provide different transport elements or generally different transport modules in the belt suspension cooler, adapted to the progress of the cooling of the metal strip or to the temperature of the metal strip during cooling.

[0018] According to a preferred embodiment of the invention, the transport element can be formed by ropes or belts or a mesh fabric or a perforated conveyor belt, which allows the gaseous fluid and/or the cooling fluid to flow through the transport element, so that the transport element can remain in the area between the upper and lower discharge elements for the gaseous fluid. This also makes it possible for the transport device to be ready for use again more quickly if required.

[0019] According to a further embodiment of the invention, it can be provided that the transport element is arranged on rollers or cylinders in a rotating manner in order to be able to influence the temperature load of the transport element via the heat dissipation by means of the rollers or cylinders. If necessary, the rollers or cylinders can be designed to be cooled if required.

[0020] According to a variant embodiment of the invention, it can be provided that the rollers or cylinders have a coating by means of which the force transmission from the rollers or cylinders to the transport element or elements can be better defined.

[0021] According to another embodiment, in order to simplify the transition from the contacted to the contactless transport state of the metal strip, it can be provided that at least the transport element of the transport device is height-adjustable. With the height adjustability, the transport element can be lowered during the formation of the floating state of the metal strip. This also makes it possible to influence an intended form of floating of the metal strip, such as a flat or sinusoidal or wavy floating of the metal strip, at an earlier stage during the changeover.

[0022] According to a further embodiment of the invention, it can be provided that the transport modules are height-adjustable independently of one another, whereby the lowering can be carried out only in sections or in stages, etc., if necessary.

[0023] For the same purpose, according to another embodiment of the invention, it can be provided that the transport elements of the transport modules are height-adjustable independently of one another.

[0024] According to one embodiment of the invention, the liquid cooling units can be arranged between discharge elements for a gaseous fluid, whereby cooling liquid can be blown off the metal strip with the gaseous fluid. This can create an improved cooling line across the width of the strip and enable targeted liquid removal from the strip surface.

[0025] This is advantageous due to the better adaptability to different band

floating coolers if, according to a further embodiment of the invention, liquid cooling units are arranged within the transport modules.

[0026] According to one embodiment of the system, the belt floatation cooler can be arranged immediately after the belt casting device. This can provide a relatively large cooling gradient window for gas cooling or gas-liquid cooling, which means that a wide variety of metals can be processed with the system. In addition, the belt floatation cooler can enable contactless transport of the metal strip after the strip run-in phase, which can enable a damage-free surface of the metal strip.

[0027] For a better understanding of the invention, it is explained in more detail with reference to the following figures.

[0028] They show in a simplified, schematic representation: [0029] Fig. 1 a section of a plant for producing a metal strip; [0030] Fig. 2 a continuous cooling device;

[0031] Fig. 3 shows a detail of a variant embodiment of a transport element in plan view;

[0032] Fig. 4 shows a detail of another embodiment of a transport element in plan view;

[0033] Fig. 5 shows an embodiment variant of a transport device.

[0034] To begin with, it should be noted that in the variously described embodiments, identical parts are provided with identical reference symbols or identical component designations, whereby the disclosures contained in the entire description can be transferred analogously to identical parts with identical reference symbols or identical component designations. The position information chosen in the description, such as top, bottom, side, etc., also refers to the figure directly described and shown, and these position information must be transferred analogously to the new position in the event of a change in position.

[0035] Fig. 1 shows a schematic section of a system 1 for producing a metal strip 2. The metal strip 2 consists in particular of a non-ferrous metal or a non-ferrous metal alloy, such as aluminum or a non-ferrous metal. However, the metal strip 2 can also consist of an iron-based material, such as steel.

[0036] The system 1 (also referred to as a “continuous casting line”) comprises a strip casting device 3 and a continuous cooling device 4, i.e. a strip floating cooler. The continuous cooling device 4 is preferably provided for the horizontal passage of the metal strip 2.

[0037] In the strip casting device 3, the metal strip is produced from a melt. The strip casting device 3 can be designed according to the state of the art, so that further details can be found in the relevant state of the art. For example, the strip casting device 3 can be a so-called belt caster, a twin roll caster, etc. The strip casting device 3 is in particular a continuously operated casting device.

[0038] The continuous cooling device 4 is arranged downstream of the strip casting device 3 in a production direction 5. The continuous cooling device 4 is described in more detail below.

[0039] The system 1 can have further units or components, such as a heat treatment device 6 in which the metal strip 2 is heated or through which the metal strip 2 passes heated. Since these further units of the system 1 can also correspond to the state of the art, they will not be discussed further to avoid repetition. The heat treatment device 6 can be arranged behind the continuous cooling device 4 or in front of it in the production direction 5 of the metal strip 2. In the preferred embodiment, however, the continuous cooling device 4 is arranged after the strip casting device 3 in the production direction 5 of the metal strip 2, in particular

or immediately thereafter, as is illustrated by the dashed line in Fig. 1. The continuous cooling device 4 can therefore be arranged at the exit of the metal strip 1 from the strip casting device 3, so that the metal strip 2 which has already been at least partially solidified can enter the continuous cooling device 5 directly.

[0040] The continuous cooling device 4 for cooling a metal strip 2 is better seen in Fig. 2, which schematically shows the continuous cooling device 4 in a side view.

[0041] The continuous cooling device 4 has at least one belt cooler 7. The continuous cooling device 4 can also have several belt coolers 7, for example two or three or four belt coolers 7 arranged one behind the other and/or next to each other. If the continuous cooling device 4 has several belt coolers 7, these are preferably designed the same. Therefore, only one belt cooler 7 will be discussed in more detail below. The explanations can be transferred to other belt coolers 7 of the continuous cooling device 4 if necessary.

[0042] The belt cooler 7 has a plurality of lower discharge elements 9 for a gaseous fluid arranged one behind the other along a direction of passage 8 of the metal belt 2 through the continuous cooling device 4 and a plurality of upper discharge elements 10 for a gaseous fluid arranged one behind the other along the direction of passage 8 of the metal belt 2. The lower discharge elements 9 are arranged at a distance from one another. The discharge elements 10 are also arranged at a distance from one another. Furthermore, the lower discharge elements 9 are arranged at a distance from the upper discharge elements 10 so that the metal belt 2 can be conveyed between the lower and upper discharge elements 9, 10 through the continuous cooling device 4.

[0043] Air is used in particular as the gaseous fluid, but another gas may also be used.

[0044] The lower and upper discharge elements 9, 10 for the gaseous fluid can be designed in accordance with the prior art. For example, they can have a housing 11 that forms or contains a supply channel for the gaseous fluid. A nozzle or several nozzles for the outflow of the gaseous fluid can be arranged or formed on the housing 11. This makes it possible to achieve high heat transfer (high heat transfer coefficient). The nozzle(s) is/are arranged or aligned in particular in such a way that the escaping gas flow is directed onto the metal strip 2. The nozzle(s) can have slot-like outlets so that the nozzle(s) is/are bar-shaped. The housing 11 or the nozzle(s) preferably extend over the entire width of the metal strip 2. If there are several nozzles, these can also be arranged relative to one another in such a way that the metal strip 2 can be exposed to a gas flow over its entire width.

[0045] To supply the lower and upper discharge elements 9, 10 with the gaseous fluid, a blower or a fan can be provided which is fluidly connected to the lower and upper discharge elements 9, 10. Several blowers or a fan can also be provided. The lower and upper discharge elements 9, 10 can be supplied with the gaseous fluid independently of one another or together.

[0046] The belt cooler 7 also has several liquid cooling units 12. The liquid cooling units 12 can be used to apply a cooling liquid to the metal belt 2. With these liquid cooling units 12, an improved, i.e. more homogeneous, cooling can be achieved. In particular, a more homogeneous cooling line (linear cooling area) can be achieved transversely to the direction of flow 8.

[0047] Water can be used as a cooling liquid. However, other liquids can also be used as cooling liquid.

[0048] The liquid cooling units 12 can be designed according to the prior art. For example, they can have a housing 13 that forms or contains a supply channel for the cooling liquid. A nozzle or several nozzles for the outflow of the cooling liquid can be arranged or designed on the housing 13, for example as flat jet nozzles, full cone nozzles, atomizing nozzles or hollow cone nozzles. The nozzle(s) is/are

in particular arranged or aligned in such a way that the emerging liquid flow is directed onto the metal strip 2. The nozzle(s) can have slot-like outlets so that the nozzle(s) is/are designed in the shape of a bar. The housing 11 or the nozzle(s) preferably extend over the entire width of the metal strip 2. If there are several nozzles, these can also be arranged in relation to one another in such a way that the metal strip 2 can be exposed to a gas flow over its entire width. For example, the nozzles can be arranged or designed in one or more rows on the housing 13 which extend in the direction of the width of the metal strip 2.

[0049] To supply the nozzle(s) with the cooling liquid, one or more pumps can be provided which are fluidly connected to the nozzle(s). The nozzles can be supplied with the cooling liquid independently of one another or together.

[0050] The liquid cooling units 12 can be arranged between the lower discharge elements 9 and between the upper discharge elements 10. They can be arranged only between the lower discharge elements 9 or only between the upper discharge elements 10. One or more lower or upper discharge elements 9, 10 can be arranged between the liquid cooling units 12. The representation chosen in Fig. 2 is therefore not to be understood as limiting the scope of the invention.

[0051] The lower and upper discharge elements 9, 10 and the liquid cooling units 12 are arranged in the continuous cooling device 4 such that they do not touch the metal strip 2 during operation of the continuous cooling device 4.

[0052] To control the lower and upper discharge elements 9, 10 and/or the liquid cooling units 12, corresponding control valves can be provided.

[0053] The continuous cooling device 4 has, between the upper and lower discharge elements 9, 10, at least one transport device 14 with at least one transport element 15 for temporarily transporting the metal strip 2.

[0054] In the embodiment of the continuous cooling device 4 shown in Fig. 2, the transport device 14 is modular and has three transport modules 16. The transport device 14 can also have fewer or more than three transport modules 16, for example two or four or five, etc., so that the transport device 14 can be adapted to different lengths of the continuous cooling device 4. The transport device 14 can also extend continuously through the continuous cooling device 4 or a section of the continuous cooling device 4 and have only a single transport element 15 that extends continuously over the entire length of the continuous cooling device 4 or the said section of the continuous cooling device 4.

[0055] The transport modules 16 of the transport device 14 are arranged one behind the other in the direction of passage 8 of the metal strip 2. However, it is also possible, alternatively or additionally, for several transport modules 16 to be arranged next to one another in the continuous cooling device 4, i.e. transversely (in particular at right angles) to the direction of passage 8 of the metal strip 2.

[0056] The transport modules 16 can be assigned one or more lower discharge elements 9 for a gaseous fluid and one or more liquid cooling units 12. For example, each of the transport modules 16 of the embodiment variant of the continuous cooling device 4 shown in Fig. 2 has two lower discharge elements 9 and one liquid cooling unit 12. However, this number should not be understood as limiting the scope of the invention. More than two lower discharge elements 9 for a gaseous fluid, for example three or four, etc., and/or more than one liquid cooling unit 12, for example two or three, etc., can also be provided per transport module 16. Preferably, the number of liquid cooling units 12 per transport module 16 is smaller than the number of lower discharge elements 9 for a gaseous fluid.

[0057] In the embodiment of the transport device 14 with the transport modules 16, preferably each of the transport modules 16 or at least several of the transport

module 16 has its own transport element 15. However, it is also possible for several transport modules 16 to share a common transport element 15.

[0058] The at least one transport element 15 serves at least temporarily to support and transport the metal strip 2 through the continuous cooling device 4, in particular at the beginning, i.e. during the strip run-in phase. This refers to the phase of the strip run in which a new strip is introduced into the continuous cooling device 4 so that the free initial section of the metal strip 2 is located therein between the lower and upper discharge elements 9, 10 for the gaseous fluid. When this initial section has left the continuous cooling device 4 again and in particular a stable process state has been established, i.e. when the strip is already being wound into a coil under tension, the strip is conveyed through the continuous cooling device 4 floating on the gaseous fluid. In order to simplify the transition between the support of the metal strip 2 and the suspension of the metal strip 2, according to a variant of the continuous cooling device 4, it can be provided that the transport element 15 is formed by ropes or belts or a mesh fabric or a perforated conveyor belt. Reference is made to Figs. 3 and 4, which show sections of a transport element 15 in the form of a "perforated belt" with openings 17 in Fig. 3 and in the form of a mesh fabric in Fig. 4.

[0059] However, it should be noted that the transport element 15 can be formed by a continuous belt (i.e. a belt without openings 17) which extends over at least 50%, for example at least 80%, of the total width of the metal strip 2 transversely to the direction of passage 8.

[0060] The number and size as well as the shape of the openings 17 can vary. For example, a proportion of between 40% and 80% of the surface of the transport element 15 can be designed as openings 17. The openings 17 can be round, square, generally polygonal or polygonal. It is also possible for the transport element 15 to have several different openings 17.

[0061] If ropes and/or several belts arranged next to one another are used, these individual elements are arranged at a distance from one another, so that the openings 17 are formed due to the spacing between the ropes and/or belts. The distance between the ropes and/or belts and their number can be selected accordingly depending on the design of the continuous cooling device 4 or the metal belt 2. For example, between two and twenty ropes and/or belts can be arranged in the continuous cooling device 4 as transport elements 15 for the metal belt 2.

[0062] In general, the transport element 15 or the transport elements 15 can consist of a metal or metal composite materials, such as metal-mineral fiber composites, in particular with glass fibers, or metal composites with ceramic particles, etc.

[0063] According to the preferred embodiment of the continuous cooling device 4, rollers 18 or rolls or generally rotatable or rotatably mounted support elements are provided for guiding the transport element 15 or the transport elements 15. In the modular embodiment, rollers 18 or rolls are provided at the corners at which the respective transport element 15 is deflected, as can be seen from Fig. 2. However, within the scope of the invention, more than these rollers 18 or rolls can generally be provided in the deflection areas, in particular if the transport element 15 covers longer distances between these deflection areas, in which further support of the transport element 15 is advantageous.

[0064] At least one of the rollers 18 or rollers (per transport module 16) may optionally be driven.

[0065] The support (and guidance) of the at least one transport element 15 can also be carried out with other, optionally driven, support elements.

[0066] It is also possible that the support elements, for example the rollers 18 or rolls, have a surface profile in order to apply a driving force to the

Transport element(s) 15. The surface profiling can be, for example, a toothing. The transport element(s) 15 can also have a surface profiling, for example a toothing, on the side facing the support elements, which interacts with the surface profiling of the support elements.

[0067] The transport element 15 or the transport elements 15 can optionally be provided with a separate cooling system, for example cooled from below (the side on which the metal strip 2 is not resting) with a liquid or gaseous cooling medium. In the embodiment with the rollers 18, these can be cooled and thus transfer the cooling effect to the transport element(s) 15.

[0068] According to a further embodiment variant, it can be provided that the rollers or cylinders 18 have a coating 19, as is indicated by dashed lines on the left lower roller 18 in Fig. 2.

[0069] The coating 19 can be a friction-reducing coating 19 in order to reduce the friction between the rollers 18 and the transport element 15. For example, the coating can be formed by Al-O3, for which purpose the rollers 18 can be anodized, for example.

[0070] However, the coating 19 can also be a friction-increasing coating 19 in order to increase the friction between the rollers 18 and the transport element 15 and to improve the power transmission between the roller 18 and the transport element 15 or between the roller and the transport element 15.

[0071] In a continuous cooling device 4, rollers 18 or rolls with different coatings 19 can also be provided. For example, both rollers 18 or rolls with a friction-reducing coating 19 and rollers 18 or rolls with a friction-increasing coating 19 can be arranged.

[0072] As already explained, in the course of the method, the transport of the metal strip 2 through the continuous cooling device 4 is preferably switched to a floating motion of the metal strip 2. In addition to the openings 17 described above or as an alternative thereto, according to a variant embodiment, it can be provided that at least the transport element 15 of the transport device 14 or the transport modules 16 is height-adjustable. For example, at least the upper support elements, for example rollers 18, can be arranged or held in a holder 20, for example a holding frame, so that they can be lowered, as is indicated in Fig. 5. In this case, when the transport element 15 is lowered, it can lose its contact with the lower support elements. It is also possible for the entire transport modules 16 or the entire transport device 14 to be designed to be lowerable, as is indicated in Fig. 2 using the right-hand transport module 16 in dashed lines. For this purpose, for example, a guide rail can be provided in which the corresponding elements of the transport device 14 are held/guided in a lowerable manner.

[0073] For lowering the respective elements of the transport device 14, a corresponding drive or drives, such as at least one electric motor, a hydraulic or pneumatic actuator, etc., can be provided.

[0074] According to a further embodiment variant, it is possible for the transport modules 16 to be height-adjustable independently of one another, so that the changeover from contact conveying of the metal strip 2 to floating conveying can be carried out step by step or in sections. In general, this allows a demand-oriented contact conveying of the metal strip 2 with at least one transport element 15. For this purpose, corresponding sensors and/or a control or regulating device can be provided in/on the continuous cooling device 4. The sensors can be used, for example, to determine the position of the metal strip 2 within the continuous cooling device 4.

[0075] The system 1 can be used to carry out a method for cooling a metal strip 2 in a continuous cooling device 4, wherein the continuous cooling device 4 has at least one strip cooler 7, which has a plurality of lower discharge elements 9 for a gaseous fluid distributed along a direction of passage 8 of the metal strip 2 and a plurality of lower discharge elements 9 for a gaseous fluid distributed along the direction of passage

8 of the metal strip 2, and which has a plurality of liquid cooling units 12 with which the metal strip 2 can be supplied with a cooling liquid, wherein the metal strip 2 is exposed during cooling to a gaseous fluid which is directed from the upper and lower discharge elements 9, 10 in the direction of the metal strip, and to a cooling liquid which is applied to the metal strip 2 emerging from the liquid cooling units 12. A free initial section of the metal strip 2 is placed on at least one transport element 15 of the transport device 14, which is arranged between the upper and lower discharge elements 9, 10, and is conveyed with the transport element 15 through the continuous cooling device 4. When or after leaving the free end section of the metal strip 2, the conveying quantity of gaseous fluid or the volume flow of gaseous fluid is increased so that the metal strip 2 is brought into a floating state within the continuous cooling device 4. In addition, at least the transport element 15 of the transport device 14 can be lowered. The increase in the volume flow of gaseous fluid can be achieved by increasing the speeds of the aforementioned fans (which can be designed as circulation fans, for example) or blowers.

[0076] If necessary, when a free end section of the metal strip 2 is reached, the suspension conveying can be converted back into the contact-guided conveying state by reversing these processes.

[0077] Finally, for the sake of clarity, it should be pointed out that, in order to better understand the structure of the system 1 or the continuous cooling device 4, these are not necessarily shown to scale.

REFERENCE SYMBOL LIST

1 plant

2 metal bands

3 strip casting device

4 continuous cooling device

5 Production direction

6 heat treatment device

7 belt coolers

8 Direction of flow

9 discharge element

10 discharge element

11 housings

12 liquid cooling unit

13 housings

14 transport device

15 transport element

16 transport modules

17 breakthrough

18 rollers

19 coating

20 bracket

Claims (14)

patent claims 1. Belt floating cooler for cooling a metal strip (2), with at least one belt cooler (7) which has a plurality of lower discharge elements (9) for a gaseous fluid distributed along a direction of travel (8) of the metal strip (2) and a plurality of upper discharge elements (10) for a gaseous fluid distributed along the direction of travel (8) of the metal strip (2), and with a plurality of liquid cooling units (12) with which the metal strip (2) can be supplied with a cooling liquid, characterized in that at least one transport device (14) with at least one transport element (15) for temporarily transporting the metal strip (2) is arranged between the upper and lower discharge elements (9, 10). 2. Belt flotation cooler according to claim 1, characterized in that the transport device (14) has a plurality of transport modules (16) which are arranged one behind the other in the direction of passage (8) of the metal belt (2). 3. Belt flotation cooler according to claim 2, characterized in that the transport modules (16) each have at least one transport element (15). 4. Belt flotation cooler according to one of claims 1 to 3, characterized in that the transport element (15) is formed by ropes or belts or a mesh fabric or a perforated conveyor belt. 5. Belt flotation cooler according to one of claims 1 to 4, characterized in that the transport element (15) is arranged on rollers or cylinders (18) in a circumferential manner. 6. Belt flotation cooler according to claim 5, characterized in that the rollers or cylinders (18) have a coating (19). 7. Belt flotation cooler according to one of claims 1 to 6, characterized in that at least the transport element (15) of the transport device (14) is height-adjustable. 8. Belt flotation cooler according to one of claims 2 to 7, characterized in that the transport modules (16) are height-adjustable independently of one another. 9. Belt flotation cooler according to one of claims 3 to 8, characterized in that the transport elements (15) of the transport modules (16) are height-adjustable independently of one another. 10. Belt flotation cooler according to one of claims 1 to 9, characterized in that liquid cooling units (12) are arranged between lower and/or upper discharge elements (9, 10) for a gaseous fluid. 11. Belt flotation cooler according to one of claims 2 to 10, characterized in that liquid cooling units (12) are arranged within the transport modules (16). 12. Plant (1) for producing a metal strip (2) with at least one strip casting device (3), in which the metal strip (2) is produced from a melt, and optionally at least one heat treatment device (6), in which the metal strip (2) is heated or through which the metal strip (2) passes in a heated state, and at least one strip floating cooler, characterized in that the strip floating cooler is designed according to one of claims 1 to 11. 13. Plant according to claim 12, characterized in that the belt flotation cooler is arranged immediately adjacent to the belt casting device (3). 14. Method for cooling a metal strip (2) in a belt cooler with at least one belt cooler (7) which has a plurality of lower discharge elements (9) for a gaseous fluid distributed along a direction of passage (8) of the metal strip (2) and a plurality of upper discharge elements (10) for a gaseous fluid distributed along the direction of passage (8) of the metal strip (2), and which has a plurality of liquid cooling units (12) with which the metal strip (2) can be supplied with a cooling liquid, wherein the metal strip (2) for cooling purposes, it is exposed to a gaseous fluid which is directed from the upper and lower discharge elements in the direction of the metal strip (2), and to a cooling liquid which is applied to the metal strip (2) emerging from the liquid cooling units (12), characterized in that a free initial section of the metal strip (2) is placed on a transport element (15) of a transport device (14) which is arranged between the upper and lower discharge elements (9, 10), and is conveyed through the belt suspension cooler by the transport element (15), that with or after leaving the free initial section, the conveying quantity of gaseous fluid is increased so that the metal strip (2) is brought into a floating state within the belt suspension cooler. Here 2 sheets of drawings