FI62236B - SLIDPLATTVENTIL - Google Patents

Description

SSr * l ΓβΙ m ^ NOTICE OF PUBLICATION, 0 0 -y s Χ & Φ lJ '' utläggningsskrift 622 36 c (45) Pate nttl issued 10 12 1932

Patent (S1) K ».lk.Va.3 B 22 D 41/08 // F 16 K 3/02, 31/122 FINLAND — FINLAND (21) Ncw ^» MkMniN-f «Mm« iwekntng 773027 (22 ) HmkwnUpUvt - AnsOknlngtdtf 12.10.77 '' (23) AlkupMvt — Glkljhettd · * 12.10.77 (41), Tullut JulkMcH - MMt effuncHt l6.04.78

Patent · ia rakistarihmilitiM ............. ,, __ '. ^, (44) Date of publication. - 31.0Ö.Ö2

Patant · och regicterityrelMn '' Anrtk »utta« d oeh «ι. * Γ * μ pubiiurad (32) (33) (31) Requested« uoHtuut -k | »rJ prlorHut 15 · 10.76 USA (US) 732867 (71) USS Engineers and Consultants, Inc., 600 Grant Street, Pittsburgh, Pennsylvania, USA (U5) (72) Earl Page Shapland, Sarasota, Florida, Patrick Dana King, Champaign, Illinois, USA (US) (7M Oy Kolster Ab (5M Sliding Valve The present invention relates to a sliding plate valve for casting or flowing molten materials such as steel, iron, aluminum, brass and glass, for materials which are only fluid at temperatures above normal ambient temperatures.

The background of the invention is generally described in U.S. Patent Nos. 311,902; 1,507,852; 3,436,023 and 3,454,201. U.S. Patent No. 3,352,465 and its reprint No. Re 27,237 disclose a refractory series valve pressed by springs against a fixed top plate, which is generally an indication of the environment in which this invention will be useful. Recently published U.S. Patent No. 3,866,806 discloses a throttling method using an adjusting cylinder to stop a closing device to shorten a full stroke.

The disadvantage of all the structures identified above is that the magnitude of the throttling movement cannot be adjusted independently of the urgent closing action of the valve. Such an operation is particularly desirable when aluminum-cooled steel flows through a continuous casting channel. The alumina formed as a result of the cooling process, 2,62236, tends to retract towards the side wall of the orifice and any associated spout, and may eventually clog both. It is therefore necessary that the valve as well as the pipe can be replaced in a continuous casting channel. This is realized in particular in the structure described in patent No. 3,352,465 (Re 27,237), by replacing an intact slab and replacing another element.

The invention is characterized in that the support frame is movably mounted relative to the top plate so that the sliding plate flow opening can be moved away from the top plate opening position to restrict the casting flow without interfering with the ability of the first transfer means to displace the sliding plate to move it along the guide surfaces of the support frame, and that the second transfer means is activatable independently of the first transfer means and its actuator is connected only to the movable support frame to move the support frame and the slide plate together relative to the top plate.

Other characteristic features of the invention are set out in claims 2 and 3.

The invention will be explained in more detail by way of example with reference to the accompanying drawings, in which: Figure 1 is a cross-sectional view of the bottom of a casting vessel described herein as an intermediate basin fitted with a sliding valve constructed in accordance with the invention; valve slide and casting tube, Figure 3 is a section similar to Figure 2 of a modified valve showing only the lateral displacement of the slide, Figure 4 is a section similar to Figure 1, of the bottom of a vessel described herein as a ladle, 5 Scissors taken along line 5-5 of Figure 5 on an enlarged scale.

62236 3 is a sectional view of a further embodiment of the invention shown mounted in a basin; separated.

Figures 1 and 2 show an intermediate basin 1 with a refractory lining 2. A fixed mounting plate 3 is attached to the bottom of the intermediate base, which holds the refractory top plate 4 in a certain place with respect to the mounting plate 3. Attached to the mounting plate 3 are support rods 5 which slidably support the slide plate support frame 6 supporting the slide plate support rails or guide surfaces 7 shown in more detail in Figure 2. The plate change cylinder 8 is connected to the slide plate support frame 6. The slide plates are then inserted 13 and at the same time pushes the used plate from point 13 to point 14. The sliding plates can be non-perforated metal pieces for closing, as shown in point 12, or they can have pouring openings, as shown in points 13 and 14. As shown in Figure 1, the unit is provided with an immersion tube 16, although it can operate without an immersion tube. The submersible casting tube 16 depends on a holder 14 supported by the support rails 10 shown in more detail in Fig. 2, which are supported by a submersible casting tube support frame 9 supported under the slide plate support frame 6.

As shown in Fig. 2, the support rails 7 and 10 are rotatably mounted in their respective frames 6 and 9 and loaded with springs so as to force the slide plate 13 against the top plate 4 and the casting tube holder 15 against the slide plate 13.

Figure 2 shows the way the throttle is performed. The support plate 6 of the sliding plate is deflected to the right so as to provide a laterally deflected position between the opening of the upper plate 4 and the opening of the sliding plate 13 and thus a throttling of the current. The support plate 6 of the sliding plate slides on the support rod 5 and in this case it is moved by a hydraulic choke cylinder 17, although it could also be moved by means of levers and screws, either manually or electrically.

In the embodiment according to Fig. 2, the support frame 9 of the immersion casting tube is rigidly connected to the support frame 6 of the sliding plate, so that when the immersion casting tube holder 15 and the immersion casting tube 16 are moved to the side together with the sliding plate 13, they remain in line with it.

In the modification shown in Fig. 3, the immersion tube support frame 9 is rigidly fixed to the fixed mounting plate 3 so that when the hydraulic cylinder 17 moves the sliding plate support frame 6 and the sliding plate 13 to the side, as shown, the immersion .

Figure 4 shows the ladle 18 and its refractory cladding 19. A fixed mounting plate 20 is mounted on the bottom of the ladle, holding the refractory top plate 21 in a predetermined position relative to the mounting plate 20 and also supporting the slide plate support frame 27 by flanged rails 28 shown in Figure 5. supporting the slide plate 25 is slidably mounted on the support frame 27.

In the position shown in Fig. 4, the guide joint 23 driven by the cylinder 22 has pulled the slide plate support 24 and the slide plate 25 to the right so far that it abuts the abutment built into the slide plate support frame 27. This would be its normal fully open position, but as shown, the throttling cylinder 26 connected between the ladle body 18 and the slide plate support frame 27 has shifted the entire slide plate support frame 27 to the right a distance of about one-third of the plate 21 opening width and thus restricts flow through the opening. The throttling could equally well be performed by moving the sliding plate support frame to the 27 positions. Which of these modes is selected depends on whether you want to strangle the front or back of the sliding plate opening. The valve can be quickly closed using the control cylinder 22 without having to use the throttle cylinder 26.

Referring now to Figure 5, the flanged rails 28 are secured to the mounting plate 20 by support screws 29. The flange portion of the rails 28 engages the flange portions of the slide plate support frame 27 which support it in a predetermined vertical position while allowing the necessary sliding movement. Stops ί 5 62236 can be attached to the rails 28 to limit the movement of the slide plate support frame 27.

Figures 6-9 indicate parts corresponding to those shown in Figures 1 and 2 by an index comma, such as the intermediate basin 1 'used as a container. The inside of the intermediate fence 1 'is covered with a refractory material 2' and a mounting plate 3 'is placed under the basin. The top plate 4 ’is immediately below the spout 1’ of the gap. The top plate 4 'is surrounded by a frame 6' and inside it a slide plate support rails or guide surfaces 1 'are mounted, along which the slide plates move by means of a drive cylinder 8' (shown in Fig. 9).

Below the slide plate support frame 6 ', a pipe support frame 9' is placed, which has support rails, generally indicated by the number 10 ', on which the pipe holder 15' is mounted. The tube holder 15 'is surrounded by metal as well as the top plate 4' and the sliding plates. The casting tube 16 'protrudes downwards from the tube holder 15'.

The throttle cylinder 17 'uses a transverse joint 30 which is rotatably attached to lever arms 31 connected to crankshafts 32. Short lever arms 33 are also attached to shafts 32 and rotatably connected to yokes 34 provided with opposite push rods 35 to act

The spring-loaded push rods 37, which are acted upon by the springs 36, rest on rocker arms 38 mounted on bearing pins 39 to force the holder of the tube holder 15 'against the slide plate 13' and to force the slide plate 13 'against the top plate 4'.

As can be seen from Figures 7 and 8, the opening of the sliding plate 13 'is elongate in the direction of the throttling axis. This shape is highly desirable to maximize the opening at the end of the casting before complete closure and vice versa to allow a relatively small overall opening when casting begins before any clogging. The elongate opening shown in Figure 7 is non-circular or oval in shape. Alternatively, other shapes may be used, for example elliptical shapes. In the fully constricted state, the bottom image of the total pouring opening is gladly substantially circular, but when the constriction is reduced, the total opening becomes more closely similar to the opening shown in Figure 7, which opening is shaded only where the blockage has occurred.

62236 In this way, maximum constriction can be achieved while maintaining a tight flow. It is further contemplated to use torn plates with different minor axes of the openings while all having the same major axis. When the length of the major shaft is a function of the total stroke of the throttling mechanism, the maximum percentage of throttling available is the same for all the different sized openings used. In the embodiment shown in Figures 6-9, the stroke of the throttling mechanism is half the length of the major axis of the opening. The elongate opening allows the use of slabs of different opening area in a mechanism with a particular throttling movement, while avoiding over-throttling, which disrupts the flow and causes large erosion in the area below the throttling point.

Claims (3)

7 62236 A sliding plate valve for a casting vessel, comprising a top plate (4, 4 ', 21) fixedly placed under the casting vessel, having an opening in open communication with the casting opening in the bottom of the vessel, a movable sliding plate (13, 13', 25) together with the top plate opening a functioning flow opening to allow flow from the casting vessel when the sliding plate is in its operative position below the top plate with the sliding plate opening aligned with the top plate opening, a support frame (6, 6 ', 27) having guide surfaces (7, 7') contacting the sliding plate to and from below the top plate, a first slide plate transfer means (8, 8 ', 23) which moves the slide plate (13, 13', 25) along the guide surfaces (7, 7 ') to and from the operating position, and a second transfer means ( 17, 17 ', 26), which moves the flow opening of the sliding plate relative to the opening of the upper plate from the position aligned with the said openings when the sliding plate is in its operating position, characterized in that the support frame s (6, 6 ', 27) is movably mounted relative to the top plate (4, 4', 21) so that the flow opening of the sliding plate can be moved away from the position of the openings relative to the opening of the top plate to restrict the flow without disturbing the first transfer means. with respect to the top plate, that only the drive member of the first transfer means (8, 8 ', 23) is operatively engaged with the slide plate (13, 13', 25) to move it along the guide surfaces (7, 7 ') of the support frame (6, 6', 27), and that the second the transfer means (17, 17 ', 26) is activatable independently of the first transfer means and its actuating member is connected only to the movable support frame for moving the support frame and the sliding plate together relative to the top plate. A valve according to claim 1, wherein the sliding plate (13 or 13 ') is slidably mounted on a support frame (6 or 6'), characterized in that said second transfer means is a liquid cylinder (17 or 17 ') / whose actuating member is connected to the support frame (6 or 6 ') to move the frame (6 or 6') to the side from the direction of movement of the first transfer means on the sliding plate. 8 62236 A valve according to claim 2, characterized in that said second transfer means comprises a fluid cylinder (17 '), the drive member of which is connected by a crank (31) to a crankshaft (32), a crank (33) connected to said crankshaft (32), and opposite push rods (35) connected to said yoke (34) for moving the sliding plate (13 ') to the side from the direction of movement of the first transfer means on the sliding plate. 9,62236 Patent Scrap;