EP0492227A1 - Device for cooling the pressing tools of a pressing machine and methods for its operation - Google Patents

Abstract

The invention relates to a device for cooling the pressing tools (9) of a pressing machine (1) for reducing the width of rolled stock, in particular the width of slabs (10) in hot wide-strip roughing trains with tool carriers (8) which are arranged on both sides at the edge of the slab, hold mutually facing pressing tools (9) and can be moved relative to one another. It is proposed that the pressing machine (1) should have at least one coolant nozzle (18) directed at the regions of the front edge (17) of each pressing tool (9), the device preferably being operated in such a way that the region of the front edge (17) of each pressing tool (9) is cooled continuously by a spray of coolant. <IMAGE>

Description

The invention relates to a device for cooling the pressing tools of an upsetting press for reducing the width of rolling stock, in particular the width of slabs in hot wide strip roughing mills with tool carriers arranged on both sides of the slab edge, receiving the mutually facing pressing tools and moving against one another, and a method for operating the cooling device.

The pressing tools of an upsetting press to reduce the width of slabs in hot wide strip roughing mills are exposed to extremely high mechanical and thermal loads. Since the temperature of the hot slab entering the upsetting press is approximately 1250 ^o C and the pressing tool is exposed to direct thermal contact with the slab during the pressing and otherwise to the radiant heat emanating from the hot slab, the pressing tool must be cooled so that operationally acceptable tool life can be achieved will.

In a known device for changing the cross section of hot slabs coming from a slab caster according to DE-OS 25 31 591, it is therefore proposed to let the cooling of the pressing tools take place by internal circulation of a medium, taking care that the working sides of the Tools are at or near the maximum permissible temperature in order to extract the least amount of heat from the slab and to avoid excessive tool wear.

However, the present invention is based on the finding that the heat flow from the front edge of the pressing tool, which comes into contact with the hot slab, to the material areas of the pressing tool, where the coolant channels are embedded for reasons of strength, takes place too slowly, and therefore because of an internal circulation of one Not enough heat can be removed from the cooling medium by the pressing tool, with the result that after a certain operating time the tool temperature settles far above the maximum permissible temperatures. A relocation of the coolant channels in the tool at a short distance from the pressing surfaces to be cooled has the consequence that the pressing surfaces of the pressing tool can only be reworked to a limited extent and its operating times are therefore reduced to an economically unacceptable extent. Furthermore, for cost reasons, it is not justifiable to coat the pressing surfaces of the tool with such high-quality materials - for example by cladding - that can withstand the extremely high operating temperatures. Such high-quality metal alloys also allow reworking of the pressing surfaces only with considerable technical effort.

The object of the invention is to design a device for cooling the pressing tools of an upsetting press, with which the pressing tool is reliably and sustainably cooled down to such maximum permissible material temperatures at which conventional temperature change-resistant materials can be used, which require multiple reworking of the highly stressed pressing surfaces of the tool allow. Inexpensive materials should also be able to be used for the pressing tool; at the same time, the service life of these tools should be increased. This object is achieved in a manner which is unexpectedly simple for the person skilled in the art in that the upsetting press has at least one coolant nozzle directed against the regions of the front edge of each pressing tool, with the aid of this coolant nozzle in a particularly expedient continuation of the invention, the area of the leading edge of each pressing tool from the outside is spray-cooled continuously with the cooling medium. Contrary to the general expectation, an almost steady temperature curve occurs after a short operating time, which remains significantly below the permissible material temperature in the area of the press surface and decreases further towards the inside of the tool. A flat jet nozzle with a predetermined scattering angle has proven to be a particularly advantageous coolant nozzle, as a result of which the cooling medium can be applied uniformly to the entire front edge of the pressing tool.

An advantageous development of the invention provides that several flat jet nozzles are combined to form a nozzle bar which is arranged above and below the middle of the slab, advantageously between two pressure rollers holding the slab down; This makes it easier to supply and distribute the cooling medium while using the tightest of spaces. If after one Another embodiment of the invention of the nozzle bar as a structural unit can be connected to at least one coolant supply line by means of a quick-connect connection, this considerably streamlines the maintenance of the nozzles. Damage to individual nozzles can be remedied at a separate maintenance station, since the damaged nozzle bar can be exchanged for a new or repaired nozzle bar.

A continuation of the invention is that the axes of the flat jet nozzles are aligned with the slab width and the distance of the pressing tool from the slab center at different angles against the front edge of the pressing tool, and that each individual nozzle is designed to be switched off or on. The flat jet nozzles can be fixed in the nozzle bar, so that individual nozzles are assigned to certain working positions of the pressing tools in the upsetting press and are then switched off when the pressing tools are moved to a new working position, e.g. B. due to changed slab width - be set; new, assigned nozzles are then switched on in accordance with the new working position of the pressing tools. Overall, the adaptation of the nozzles to the various working positions of the pressing tools is thereby considerably simplified. It is expedient that the nozzle bar is equipped in sections with several rows of nozzles, each row of nozzles is connected to a separate coolant line, and each row of nozzles is designed to be switched off or on. The assignment of individual rows of nozzles to different working positions of the pressing tools increases and evenens the effect of the spray cooling of these flat jet nozzles.

The ability to switch off or connect entire rows of nozzles in the nozzle bar also allows the area of the front edge of each pressing tool to be acted upon from the outside and past the slab with a cooling medium in the form of spray cooling during the movement phase that is lifted from the slab edge. In this case, the control of the nozzle valves is expediently coupled to the control of the pressing tools. The coolant is largely kept away from the slab, in particular the edge of the slab, so that the deformation energy introduced into the slab by the pressing tools is sufficient to compensate for the heat loss of the slab by heat radiation. A further embodiment of the invention provides that in addition to the spray cooling of the pressing tool applied from the outside, this pressing tool is cooled internally. In this case, the coolant channels in the pressing tool can be moved back from the front edge of the tool to such an extent that multiple reworking of the pressing surfaces of the pressing tool is ensured.

Figur 1

Die Anordnung von gegen die Preßwerkzeuge gerichteten Kühldüsen oberhalb und unterhalb der Brammenmitte.

Figur 2

Die Anordnung eines mit mehreren Kühldüsen versehenen Düsenbalkens zwischen den Niederhalterollen der Stauchpresse in einer Seitenansicht.

Figur 3

Der Düsenbalken mit Flachstrahldüsen in vergrößerter Darstellung.

Figur 4

Der Düsenbalken gem. Figur 3 teilweise im Schnitt.

The invention is described in more detail using an exemplary embodiment of a cooling device for the pressing tools of an upsetting press. Show it:

Figure 1

The arrangement of cooling nozzles directed against the pressing tools above and below the center of the slab.

Figure 2

The arrangement of a nozzle bar provided with a plurality of cooling nozzles between the hold-down rollers of the upsetting press in a side view.

Figure 3

The nozzle bar with flat jet nozzles in an enlarged view.

Figure 4

The nozzle bar acc. Figure 3 partially in section.

FIG. 1 shows an upsetting press 1 with a press frame, consisting of two upper and two lower uprights 2, 3 and two crossbars 4, 5 connecting the uprights, the lower uprights 3 resting on a foundation 6. The upsetting press also has two crankcases 7, in which an eccentric drive (not shown in more detail) for the translational movement of the tool carrier 8 and the pressing tool 9 are arranged. The slab 10 to be compressed is located between the pressing tools 9 of the upsetting press 1. The slab 10 is moved through the upsetting press on a roller table (not shown in more detail). In the area of the pressing tools 9, two hold-down rollers 11 (FIG. 2) are arranged above and below the slab. The eccentric drive for tool carrier 8 and pressing tool 9 located in the crankcase 7 is driven by an articulated shaft 12 which is connected to a drive motor 14 via a gear 13. The position of the crankcase 7 in the press frame and thus the position of the pressing tools in relation to the width of the slab is adjusted with the aid of the adjusting device 15. By means of the drive devices of the upsetting press, namely drive motor 14, gear 13, cardan shaft 11 and eccentric drive in the crankcase 7, the tool carrier 8 and the pressing tool 9 are moved in the direction of arrow 16 against the edges of the slab in the horizontal direction, whereby the slab by prescribed dimensions in the width is reduced. Since the slab temperature is around 1250 ^o C and the pressing tool acts on the slab edge during the pressing period, it is subjected to high mechanical and thermal stress. According to the invention, it is therefore proposed, for the purpose of cooling the pressing tools, to provide the upsetting press with a plurality of coolant nozzle 18 directed against the regions of the front edge 17 of each pressing tool 9. The coolant nozzles 18 are designed as flat jet nozzles with a predetermined scattering angle 19 and a plurality of flat jet nozzles 18, 18 ', 18'',18''' are combined to form a nozzle bar 20 which is arranged above and below the slab center 21.

A special compression position for a slab is shown in FIG. 1, the axes of the flat jet nozzles 18 being directed above and below the slab 10 against the front edge 17 of the tool. If, in some cases, wider or narrower slabs are to be pressed in a reducing manner, the flat jet nozzles 18 in the nozzle bar 20 are switched off and, for example, the flat jet nozzles 18 ', the axes of which are now aligned with the new slab width, are switched on. The nozzles of the nozzle bar are supplied from a container 22 with cooling medium, preferably water, which is supplied by means of a pump 23. The connection and disconnection of the flat jet nozzles in the nozzle bar is carried out with the aid of switchable valves 24 which are arranged in the individual supply line 25 assigned to the respective flat jet nozzle.

FIG. 2 shows the arrangement of the nozzle bar 20 above and below the slab 10 between the hold-down rollers 11. The nozzle bar 20 can be seen as a unit with flat jet nozzles integrated in this unit, the nozzle bar being connected to the water supply lines 25 by means of quick-connect connections 26.

FIG. 3 and FIG. 4 show the nozzle bar 20 and the flat jet nozzles 18 arranged in the nozzle bar, according to which the nozzle bar is equipped in sections with several nozzle rows 18, 18 ', 18'',18''' and each row of nozzles has a separate connection bore 27, 27 '. , 27 '', 27 '''is connected. As described above, each row of nozzles can be switched off or on individually. The row of nozzles 18 is connected, for example, to the connection bores 27, in the nozzle bar and to the connection head 28 and the associated connection line (FIG. 4). The row of nozzles 18 '''is then connected to the connection bore 27''' and to the connection head 28 '''and the associated connection line. The connecting lines 28 and 28 '''can each be quickly coupled or uncoupled to the water supply line 25 via a flange 29, so that the nozzle bar 20 as a structural unit can be quickly replaced by a new nozzle bar. In FIG. 4, the scattering angle 19 specified for each flat jet nozzle is indicated schematically, as are the axes 30 ^{o of} the flat jet nozzles aligned at different angles 1 or 2, which are fixed according to the slab width and the distance of the pressing tool from the slab center.

In the operation of the upsetting press, the best cooling of the pressing tools can be brought about if the area of the front edge of each pressing tool is continuously spray-cooled from the outside with the cooling medium, preferably water. After a short operating time, a thermal steady state has set in, so that the temperature of the front edge of the press tool remains below the maximum permissible material temperature. The temperature drops further inside the tool. A slightly better cooling effect for the press tool can be achieved if in addition to that Spray cooling applied from the outside internally cools the press tool, for example, by means of coolant channels (not shown in detail) which are additionally arranged in the press tool at a distance from its front edge 17 and are connected to a coolant supply. However, this is associated with a technically higher effort. In these cases, materials that are resistant to temperature changes can be used for the pressing tool, the production of which is economically advantageous and the pressing surfaces can be reworked several times with the expected effort. Satisfactory cooling results for the pressing tool can also be achieved if the pressing tool is spray-cooled only during the process of upsetting a slab and not in the pause times between two slabs to be processed, or if the area of the leading edge of each pressing tool during the movement phase lifted from the slab edge coolant in the form of a spray cooling is applied to the outside and past the slab. Here, however, heat-resistant materials would have to be used, the cooling intensity of the spray cooling also being regulated in accordance with the maximum permissible temperatures for the heat-resistant material of the pressing tool.

It is within the scope of the invention if at least one coolant nozzle is arranged in a guide which can be pivoted into the region of the front edge of the press tool, or if the coolant jet tracks the movement of the front edge of the press tool in a different manner

Reference symbol overview

1

Upset press

2, 3

Stand spar

4, 5

Querholm

6

foundation

7

Crankcase

8th

Tool carrier

9

Press tool

10th

Slab

11

Hold-down roll

12

PTO shaft

13

transmission

14

Drive motor

15

Adjusting device

16

Movement arrow

17th

Front edge of the press tool

18th

Coolant nozzle / flat jet nozzle

19th

Scattering angle

20th

Nozzle bar

21

Slab center

22

H2O container

23

pump

24th

Valve

25th

supply line

26

Quick connect

27th

Connection hole in the nozzle bar

28

Connection head / connection line

29

flange

30th

Nozzle axis

Claims (17)

Device for cooling the pressing tools of an upsetting press for reducing the width of rolled material, in particular the width of slabs in hot wide strip roughing mills with tool carriers arranged on both sides of the slab edge and receiving the mutually facing pressing tools and movable against each other,
characterized,
that the upsetting press (1) has at least one coolant nozzle (18) directed against the regions of the front edge (17) of each pressing tool (9). Cooling device for the pressing tool according to claim 1,
characterized,
that the coolant nozzle (18) is designed as a flat jet nozzle with a predetermined scattering angle (19). Cooling device for the pressing tool according to claim 1 or 2,
characterized,
that several flat jet nozzles (18) are combined to form a nozzle bar (20) which is arranged above and below the middle of the slab (21). Cooling device for the pressing tool according to claim 1, 2 or 3,
characterized,
that the nozzle bar (20) is arranged between two pressure rollers (21) holding down the slab. Cooling device for the pressing tool according to at least one of claims 1 to 4,
characterized,
that the axes (30) of the flat jet nozzles (18) in accordance with the slab width and the distance of the pressing tool (9) from the slab center (21) are aligned at different angles () against the front edge (17) of the pressing tool (9), and that each individual nozzle (18) can be switched off or switched on by a valve (24). Cooling device for the pressing tool according to at least one of claims 1 to 5,
characterized,
that the nozzle bar (20) is partially equipped with several rows of nozzles (18, 18 ', 18'',18'''), each row of nozzles is connected to a separate coolant line (27, 28) and each row of nozzles can be switched off by means of a valve (24) or is designed to be switchable. Cooling device for the pressing tool according to at least one of claims 1 to 6,
characterized,
that the nozzle bar (20) can be connected as a structural unit by means of a quick-connect connection (26) to at least one coolant supply line (25). Cooling device for the pressing tool according to at least one of claims 1 to 2,
characterized,
that at least one coolant nozzle (18) is arranged in a guide which can be pivoted into the region of the front edge (17) of the pressing tool (9). Cooling device for the pressing tool according to at least one of claims 1 to 8,
characterized,
that additional coolant channels are arranged in the press tool at a distance from its front edge. Operating method for the device for cooling the pressing tools of the slab sizing press according to claims 1 to 9,
characterized,
that the area of the front edge of each pressing tool is continuously spray-cooled from the outside with a cooling medium. Operating method for the device for cooling the pressing tools of the slab sizing press according to claims 1 to 9,
characterized,
that the area of the front edge of each pressing tool is acted upon from the outside and past the slab with a cooling medium in the form of a spray cooling during the movement phase raised from the slab edge. Operating method for the device for cooling the pressing tools of the slab sizing press according to claims 1 to 9,
characterized,
that the area of the leading edge of each pressing tool is not spray-cooled in the pause between the upsetting of individual slabs. Operating method according to at least one of claims 10 to 12,
characterized,
that in addition to the spray cooling of the pressing tool applied from the outside, there is internal cooling of the pressing tool. Operating method according to at least one of claims 10 to 13,
characterized,
that the cooling medium is directed as a fluid coolant jet with a predetermined scattering angle from at least one side against the front edge of the tool. Operating method according to at least one of claims 10 to 14,
characterized,
that a bundle of coolant jets can be switched on or off according to the width of the slab and the position of the pressing tool relative to the slab edge. Operating method according to at least one of claims 10 to 15,
characterized,
that the cooling intensity of the coolant jets and / or the internal cooling of the press tool is regulated in accordance with the maximum permissible temperature for the material of the press tool. Method according to at least one of claims 10 to 16,
characterized,
that the coolant jet follows the movement of the front edge of the press tool in a controlled manner.

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