The invention relates to a sliding closure at the outlet of a metallurgic container, with a housing, a closing plate arranged therein, at least one longitudinally displaceable closing plate and with a cover which can be fastened to the housing by means of a bracing mechanism, wherein the closing plates can be pressed against one another by the bracing mechanism via the cover, this according to the preamble of claim 1.
A known sliding closure according to document EP-A-0 891 829 has a housing which can be fastened to the container, in which is accommodated a fire-proof closing plate stationary at the top and bottom, as well as a fire-proof slide plate which can be moved forwards and backwards between these by a power unit. The stationary closing plates are fixed in a cover or in the housing, whereas the slide plate is fastened in a metal frame coupled to the power unit. The cover is fastened to the housing in releasable manner by clamping screws and blocked by blocking means in displacement direction of the slide plate which can move forwards and backwards, meanwhile an adjustment of same, occurring perpendicular to the displacement direction, is made possible.
In a different embodiment, with a sliding closure with a casting tube changing device, the cover arranged on the top side of the housing is pivotably housed on this housing, and clamping screws which can pivot on the housing are attached to same to press together the closing plates. However, these clamping screws have to be fastened or released individually, and care must be taken that they are tightened with a specific torque to function faultlessly.
The object of the invention is to develop a sliding closure of the type named at the outset, such that the cover can be closed simply or opened at or by the housing to change the closing plates, and in so doing, an optimal bracing of the closing plates and furthermore a tight enclosing of same is guaranteed by the housing and by the cover during operation.
The object is achieved according to the invention according to the feature of claim 1.
This bracing mechanism, by means of which the cover can be braced to the housing, has, according to the invention, clamping levers pivotably housed on either side of the housing, and supports which cooperate with same, with contact surfaces which are associated either with the housing or the cover.
In this way, by this bracing mechanism according to the invention, the closing plates can always be braced against one another uniformly and optimally, even after many operational uses.
Very advantageously, two clamping levers are pivotably housed on either side of the housing or cover, wherein they are each arranged pivotable against one another or away from one another on both sides. This allows for a uniform bracing of the closing plates.
The bracing mechanism has an adjusting member for the respective actuation of the clamping levers, which member is arranged laterally displaceable in longitudinal direction transverse to the bracing direction of the closing plates, wherein the member is connected to the one clamping lever in articulated manner at one end and to a preferably manually rotatable axis for actuating same at the other end.
The invention, as well as further advantages of same, are explained in more detail below using embodiment examples, with reference to the drawings. There are shown in:
According to
Closing plates 13, 14, 16 are clamped in housing 12 or in cover 15 in routine manner, as is explained at length in patent specification EP 2 670 546 B1.
Cover 15 is fastened to housing 12 by means of a bracing mechanism 20 and, in so doing, closing plates 13, 14, 16 are pressed against one another via cover 15, in order to ensure leak tightness between these.
According to the invention, bracing mechanism 20 has, preferably on both sides of the housing 12, two opposing pivotably housed clamping levers 21, 22 and supports 23, 24 cooperating with same, wherein clamping levers 21, 22 are each pivotably housed in their central region on axes of rotation 26, 27 laterally at the housing 12, while supports 23, 24 are attached laterally to cover 15.
Clamping levers 21, 22 are housed in articulated manner on one end by means of an axis 28, 29 each on an adjusting member 30 which can be actuated by an axis 34, and equipped with a sliding element 21′, 22′ which grips the support 23, 24 at the other end, with the result that they grip the supports upon bracing, and can be pivoted away from same when released.
Very advantageously, two clamping levers 21, 22 are arranged symmetrical to one another on either side of housing 12, each with an adjusting member 30. This axis 34 extends approximately over the width of housing 12 and is coupled to adjusting member 30 on both sides of housing 12, with the result that, when this axis 34 is rotated, for example by means of a removable spanner, clamping levers 21, 22 move in the same direction simultaneously on either side of housing 12 and engage in supports 23, 24 or are released from same.
Advantageously, adjusting member 30 and clamping levers 21, 22 are arranged on the two opposing sides of box-shaped housing 12, running parallel to the displacement direction of longitudinally displaceable closing plate 14, whereas hinge 11 and power unit 18 are positioned on the narrow, transverse sides. Additionally, when braced, clamping levers 21, 22 are oriented with their longitudinal extension in bracing direction of sliding closure 10, as can be seen in
Expediently, sloping contact surfaces 23′, 24′ are arranged at each of supports 23, 24 such that, when braced, clamping levers 21, 22 each engage approximately in their center, in order that, depending on the extent and tolerances of closing plates 13, 14, 16 and the mechanism, they can be adjusted in their operating state in one or other direction on these contact surfaces 23′, 24′.
Each of the contact surfaces 23′, 24′ of supports 23, 24 is provided with a gradient angle α from 0 to 40°, for example 20°, with the result that sliding elements 21′, 22′, such as rollers or hooks, run in bracing direction of the closing plates in the closing process. The frictional force between sliding elements 21′, 22′ and supports 23, 24 changes depending on the gradient angle α. In practice, it has been shown that the best strength or friction ratios are produced with a gradient angle α of more than 0°, preferably 10 to 45°.
Adjusting member 30 of bracing mechanism 20 provided for actuating the two clamping levers 21, 22 extends laterally in the housing 12 transverse to the bracing direction or along the closing plates. It consists of a longitudinal guide element 32 with an integrated spring member 33 and a pivot lever 31 guided longitudinally from same. Guide element 32 is rotationally connected to one clamping lever 21 at one end via this axis 28 and to preferably manually rotatable axis 34 at the other end, outside of the housing 12. On one hand, the guide element 32 comprises a rod with the linkage of the clamping lever 21 and on the other hand, a rail 32′ with the receiver of axis 34 and a guide groove 39 for axis 29 of pivot lever 31 at the clamping lever 22. Spring member 33, e.g., a helical spring, designed as compression spring, is pushed up on the rod, which member is stabilized on a stop 36 in the rod and on a piston member 37 which can be displaced in limited manner against same. Furthermore, this rod and the spring member 33 are housed in a protective channel 38 in housing 12.
Axis 34, housed in the end of rail 32′, is also rotationally connected to pivot lever 31 by a toggle lever joint 35. There are housed by this a lever 35′ on one side on axis 34, and on the other side, on a bolt 31′ at the end of pivot lever 31. The latter is bent to be U-shaped, whereby it strikes against axis 34, as illustrated in
To close or open cover 15, axis 34 is moved or pivoted, manually or by a rotary drive (not visible), and with it, adjusting member 30 is moved or pivoted with clamping levers 21, 22 from the position according to
During pivoting, also simultaneously, guide element 32 is pushed into housing 12 and axis 34 also moves with it in the same direction. Accordingly, the other, opposite clamping lever 21 is pressed about axis 26 against the other support 23 of folded cover 15. When the rod is pushed, spring member 33 is quasi pushed by piston member 37 against stop 36, causing a spring compressive force against clamping levers 21, 22 and thus a bracing force on the covers and closing plates. Toggle lever joint 35 acts on the opposite side of adjusting member 30 and with same the pivot lever 31, and locking takes place due to pivoting about the dead center, in which the bolt 31′ comes to lie behind the longitudinal axis of guide element 32 in bracing direction.
According to
Thermal expansions or depletion and tolerances of the fire-proof closing plates and/or of the housing or the mechanism can thus be compensated for overall, with the result that an approximately equal compressive force is always enacted. With the springs it is additionally ensured that, at any time, cover frame 19 presses with approximately equal force on a rope seal 43, 46 integrated in housing 12, which seal seals all around between housing 12 and cover frame 19. Regardless of the fitting or relative cover position, this rope seal 43 is thus constantly under strain, and therefore also not overstressed. Furthermore, a rope seal 46 is advantageously introduced, likewise all around between cover frame 19 and closing cover 15.
This plate 42 with supports 23, 24 on each of the outer sides of closing cover 15 is furthermore additionally provided with a centering element 44, which engages laterally, approximately play-free, in a recess 45 at housing 12, in order that cover 15 connected to plate 42 is fixed in displacement direction of central closing plate 14.
The invention is sufficiently disclosed using the above embodiment examples. However, self-evidently, it could also be carried out using further variants.
As with a conventional slide gate closure, it may also contain only two closing plates. The movable closing plate would be advantageously integrated inside a slider unit which can be pushed in and out by a power unit.
With the bracing mechanism, in principle only one pivotably housed clamping lever, needing to be oriented against one another, could be provided on either side of the housing.
This bracing mechanism could also be attached to the sliding closure rotated about 180°, i.e., the adjusting member would then be attached to the cover and the supports to the housing, analogously. Instead of on the housing, the clamping levers would alternatively be pivotably housed on the cover, wherein they could pivot against one another with each sliding element at the end and simultaneously would engage with a contact surface of the support vice versa on the housing.
Contact surfaces 23′, 24′ each running slopingly on support 23, 24 could also be designed as rollers or the like. Preferably, the sliding elements of the clamping levers would then be provided as hooks with a flat bearing. This gradient angle (a) could theoretically also be measured at 0°, with the result that the sliding elements would run transverse to the bracing direction of the closing plates during the closing process.
In principle, such a bracing mechanism with an adjusting member 30 and two clamping levers could be provided also only on one side of the housing, whereas on the other side, a hinge for pivoting the cover would be provided on the housing.
Number | Date | Country | Kind |
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20186977 | Jul 2020 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2021/065008 | 6/4/2021 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2022/017673 | 1/27/2022 | WO | A |
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