JP5606184B2 - Sliding nozzle device - Google Patents

Description

  The present invention relates to a sliding nozzle device that replaces a sliding nozzle provided at the bottom of a molten metal container such as a tundish or ladle for steelmaking.

  A steel outlet formed at the bottom of a molten metal container such as a tundish or a ladle is provided with a sliding nozzle device for controlling the amount of steel output from the molten metal.

  A conventional sliding nozzle device (see, for example, Patent Document 1) is shown in FIG. The bottom 50 of the molten steel storage pan is provided with a steel outlet 50a for molten steel, and an upper nozzle 60 having an outlet hole 60a in the center is attached to the steel outlet 50a. A sliding nozzle device 70 is attached to the lower end portion of the upper nozzle 60.

  The sliding nozzle device 70 includes a base plate 71 provided with a through hole 71 a communicating with the outflow hole 60 a of the upper nozzle 60, a sliding nozzle 72 slidably attached to the lower surface of the base plate 71, and a slide for sliding the sliding nozzle 72. Means 73. The sliding nozzle 72 includes a nozzle plate 721 formed with a through hole 721a slidably disposed on the lower surface of the base plate 71, and a lower nozzle 723 formed with a nozzle hole 723a disposed below the nozzle plate 721. ing.

JP-A-6-339757

  The sliding nozzle 72 is replaced periodically or every time the inner walls of the through hole 721a and the nozzle hole 723a are melted or clogged each time the hot water is discharged. In the case of the above-described conventional sliding nozzle device, it is necessary to stop the hot water operation, remove the sliding nozzle 72 from the base plate 71, and attach a new sliding nozzle. That is, in the conventional sliding nozzle device 70, it takes time to replace the sliding nozzle 72, and the hot water must be stopped for a long time.

  In order to quickly replace the sliding nozzle, it is necessary to provide a plurality of sliding nozzles. However, since the conventional sliding nozzle device guides sliding of the sliding nozzle in one direction, a plurality of sliding nozzles must be aligned and guided in one direction. As a result, there is a problem that the sliding nozzle device becomes longer and larger.

  The present invention was devised in view of the above-described problems of the prior art, and an object of the present invention is to provide a sliding nozzle device that can quickly replace a sliding nozzle and can be downsized.

  The present invention made in order to solve the above-mentioned problems is a sliding nozzle device that causes a molten metal to flow out from a molten metal outflow hole at the bottom of the molten metal container. A base plate having holes, a plurality of sliding nozzle holding members slidably disposed along a first direction on a lower surface of the base plate, and a second crossing the first direction on the plurality of sliding nozzle holding members A sliding nozzle housed slidably along the direction of the first, a first drive means for sliding the plurality of sliding nozzle holding members along the first direction, and the sliding nozzle along the second direction. And slide the nozzle hole to a position where the nozzle hole communicates with the through hole of the base plate. And having a kinematic means.

  Since a plurality of sliding nozzles are slidably provided around the melt outflow hole at the bottom of the molten metal container, even if one sliding nozzle is clogged, it can be quickly replaced with another sliding nozzle.

  Further, since the sliding nozzle is accommodated in the sliding nozzle holding member slidable in the first direction so as to be slidable in the second direction intersecting with the first direction, the sliding direction can be changed. As a result, it is not necessary to align a plurality of sliding nozzles in a straight line, and the sliding nozzle device can be miniaturized.

  In the above sliding nozzle device, a plurality of preliminary sliding nozzles slidably disposed along the second direction on the lower surface of the base plate, and the plurality of preliminary sliding nozzles are slid along the second direction. It is good to have the 3rd drive means accommodated in the said sliding nozzle holding member (Claim 2).

  Even if the sliding nozzle of the sliding nozzle holding member disappears, it can be quickly replaced with a preliminary sliding nozzle, and the number of replenishment of the sliding nozzle can be reduced.

  Since a plurality of sliding nozzles are slidably provided around the melt outflow hole at the bottom of the molten metal container, even if one sliding nozzle is clogged, it can be quickly replaced with another sliding nozzle.

  Further, since the sliding nozzle is accommodated in the sliding nozzle holding member slidable in the first direction so as to be slidable in the second direction intersecting with the first direction, the sliding direction can be changed. As a result, it is not necessary to align a plurality of sliding nozzles in a straight line, and the sliding nozzle device can be miniaturized.

It is a schematic side view of the sliding nozzle device according to the first embodiment. FIG. 2 is a top view of FIG. 1. FIG. 3 is a partial cross-sectional view taken along line AA in FIG. 2. FIG. 3 is a partial sectional view taken along line B-B in FIG. 2. It is an upper view of the sliding nozzle apparatus which concerns on Embodiment 2. FIG. It is sectional drawing of the conventional sliding nozzle apparatus.

  Embodiments of the present invention will be described in detail with reference to the drawings.

  (Embodiment 1) FIG. 1 is a schematic side view of a sliding nozzle device according to this embodiment, and FIG. 2 is an upper view looking up from below. 3 is a partial cross-sectional view taken along line AA in FIG. 2, and FIG. 4 is a partial cross-sectional view taken along line BB in FIG.

  The sliding nozzle device shown in FIGS. 1 and 2 is a device that causes a molten metal to flow out from a molten metal outlet hole at the bottom of the molten metal container. A plurality of sliding nozzles 3 are provided to quickly replace the sliding nozzles, and the sliding direction of the sliding nozzles 3 is bent by 90 ° in plan view in order to reduce the size of the apparatus.

  The sliding nozzle device includes a base plate 1 provided with a through hole 1a provided at the bottom of the molten metal container and communicating with the molten metal outflow hole, and a straight line L1 along the horizontal direction on the lower surface side of the base plate 1 (first direction indicated by an arrow A1). And a plurality of sliding nozzle holding members 2 slidably arranged along the.

The sliding nozzle device also includes a first drive unit 4 that slides the sliding nozzle holding member 2 along a first direction indicated by an arrow A1, and a sliding nozzle 3 accommodated in the sliding nozzle holding member 2 in the first direction. A second drive means 5 that is slid along a second direction (direction indicated by an arrow A2) that intersects with the nozzle hole 3a to a position (use position P ₁ ) that communicates with the through hole 1a of the base plate 1; It has.

  The sliding nozzle 3 includes a rectangular nozzle plate 3b having a side surface 3b1 along the second direction A2 at the top.

In the sliding nozzle device, the nozzle plate lower surface end portion 3b2 along the second direction A2 of the sliding nozzle 3 slid to the position communicating with the through hole 1a (usage position P ₁ ) is directed upward (the lower surface of the base plate 2). A pair of pressing means 6 to be pressed is provided.

  As shown in FIG. 3, the sliding nozzle holding member 2 is provided with a straddling portion 2a straddling the rail 1b extending in the first direction A1 (the direction intersecting the paper surface in FIG. 3), and the first direction A1. Can slide along.

  Further, as shown in FIG. 1, the sliding nozzle holding member 2 guides the sliding nozzle 3 to slide in a second direction A2 that intersects the first direction A1 (direction intersecting the paper surface in FIG. 1). The guide part 2b and the receiving part 2c which receives the nozzle plate 3b of the sliding nozzle 3 from the bottom are provided. The guide portions 2b are opposed to each other. The receiving portions 2c are also opposed to each other.

  The sliding nozzle holding member 2 accommodates the sliding nozzle 3 so as to be slidable in the second direction A2 intersecting the first direction A1.

Also, to prevent the falling of the sliding nozzle 3, a pair of fixed guide member 7 for guiding the sliding of the sliding nozzle 3 along the second direction A2 (toward the use position P ₁₎ is mounted on the base plate 1 Yes. As shown in FIG. 2, the fixed guide member 7 is located between the standby position P ₀ and the use position P ₁ . As shown in FIG. 4, the fixed guide member 7 has an L-shaped cross section including a receiving portion 7a that receives the nozzle plate 3b from below and a guide portion 7b that guides sliding of the sliding nozzle 3.
The fixed guide member 7 is
The first drive means 4 and the second drive means 5 are formed by, for example, a pneumatic or hydraulic cylinder device, but may be a belt conveyor formed by a motor drive device in some cases.

  The pressurizing means 6 includes a plurality of independent arm-shaped pressurizing plates (keyboards) 6a that are rotatably supported on a shaft 6b parallel to the second direction A2. The other end 6a2 of the pressure plate 6a is pressed down by pressing one end 6a1 far from the sliding nozzle 3 of the pressure plate 6a downward (upward with respect to the paper surface in FIG. 2) with a pressure device (not shown). The nozzle plate 3b of the sliding nozzle 3 is pressed against the base plate 1 by being pushed upward (downward with respect to the paper surface in FIG. 6). The pressurizing device (not shown) is formed by, for example, a cylinder device such as air pressure, hydraulic pressure, or a spring, or a motor driving device.

Next, the operation of the sliding nozzle device of the present embodiment, for example, a new sliding nozzle to the nozzle hole 3a of the sliding nozzle 3 shown by the dotted line in the use position P ₁ in communication with the hole 1a is increased by melting The case of replacement will be described.

First, while continuing to press the sliding nozzle 3 indicated by the dotted line by the pressurizing means 6, the sliding nozzle holding member 2 is accommodated on the straight line L2 (standby position P ₀ ) passing through the through hole 1a and intersecting the straight line L1. The new sliding nozzle 3 is slid in the second direction A2 by the second driving means 5. At this time, the side surface 3b1 of the nozzle plate 3b of the sliding nozzle 3 is guided in the second direction A2 by the guide portion 2b of the sliding nozzle holding member 2 and the fixed guide member 7.

The second driving means 5 pushes the sliding nozzle 3 indicated by a dotted line where the sliding nozzle 3 is located at the position of the through hole 1a (use position P ₁ ) along the straight line L2 to the use position P ₁ communicating with the through hole 1a. Controlled to stop.

Then, a sliding nozzle holding member 2 on the left side in the first driving means 4 is slid in the first direction A1, a sliding nozzle holding member 2 in the middle is located at the standby position P ₀ on the straight line L2, a series of operations finish.

Sliding nozzle device of the present embodiment, a plurality of sliding nozzle 3 arranged in the first direction A1, a dotted line which is slid in a second direction A2 that intersects the first direction A1, it is positioned in the use position P ₁ Since it replaces with the damaged sliding nozzle 3 shown, it does not become long in the first direction A1 and is small.

  In addition, since the sliding nozzle 3 is slid in the first direction A1 and then slid in the second direction A2 intersecting the first direction A1, the sliding nozzle holding member 2 having no movable part is used. Excellent durability.

  (Embodiment 2) FIG. 5 is a top view of a sliding nozzle device according to this embodiment as viewed from below. The same components as those of the sliding nozzle device of the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

  The sliding nozzle device of the present embodiment is different from the sliding nozzle device of the first embodiment in the following points.

  That is, the sliding nozzle device according to the present embodiment includes a plurality of preliminary sliding nozzles 3A and 3B that are slidably disposed along the second direction A2 on the lower surface side of the base plate 1, and are arranged along the second direction A2. And third driving means 8A and 8B which are slid and accommodated in the sliding nozzle holding member 2. 7A and 7B are fixed guides for guiding the preliminary sliding nozzles 3A and 3B in the second direction A2.

  Further, the sliding nozzle device of the present embodiment slides the sliding nozzle discharged along the straight line L2 from the position of the through hole 1a downstream (in the direction of arrow A2) of the through hole 1a and discharges it. A pair of fixed guides 9 are provided.

  The preliminary sliding nozzle 3A is arranged on a straight line L2a (parallel to the straight line L2) that is separated from the straight line L2 by a distance D to the left (one side) in the figure. Further, the preliminary sliding nozzle 3B is disposed on a straight line L2b (parallel to the straight line L2) that is separated from the straight line L2 by a distance D to the right (the other side) in the figure.

  Further, the two sliding nozzle holding members 2 are connected by a connecting member 2d at a predetermined interval, and are slid left and right on the straight line L1 along the first direction A1 by the distance D by the first driving means 4. It is supposed to be.

Next, the operation of the sliding nozzle device of the present embodiment is changed from the state shown in FIG. 4 to a new sliding because, for example, the nozzle hole of the sliding nozzle that is in the use position P ₁ and communicates with the through hole 1a is melted and enlarged. The case where it replaces with a nozzle is demonstrated.

First, while the pressure of the sliding nozzle at the use position P ₁ by the pressurizing means 6 is continued, the sliding nozzle holding member 2 on the straight line L2 (standby position P ₀ ) passing through the through hole 1a and intersecting the straight line L1 is applied. The accommodated sliding nozzle 3 is slid in the second direction A2 by the second driving means 5. At this time, the side surface 3b1 of the nozzle plate 3b of the sliding nozzle 3 is guided in the second direction A2 by the guide portion 2b of the sliding nozzle holding member 2 and the fixed guide member 7.

In the second drive means 5, the sliding nozzle 3 at the standby position P ₀ pushes out the sliding nozzle at the position of the through hole 1a (use position P ₁ ), and stops at the use position P ₁ communicating with the through hole 1a. To be controlled.

Next, the first sliding means 4 slides the left sliding nozzle holding member 2 by the distance D in the first direction A1 by the first driving means 4 so that the left sliding nozzle holding member 2 is positioned at the standby position P ₀ on the straight line L2, and is empty. The right sliding nozzle holding member 2 that has become is positioned on a straight line L2b that intersects the straight line L1.

  Next, the preliminary sliding nozzle 3B is slid in the second direction A2 by the third driving means 8B and accommodated in the empty sliding nozzle holding member 2 on the straight line L2b.

Next, when the nozzle hole of the sliding nozzle at the use position P ₁ is melted, the sliding nozzle 3 accommodated in the left sliding nozzle holding member 2 positioned at the standby position P _{0 is} moved to the second position by the second driving means 5. slide the direction A2 of, extruding a sliding nozzle was in use position P _1.

Next, the sliding nozzle holding member 2 on the left side emptied by the first driving means 4 is slid by a distance D in the direction opposite to the first direction A1, and is positioned on the straight line L2a intersecting the straight line L1. The right sliding nozzle holding member 2 in which the nozzle 3B is accommodated is positioned at the standby position P ₀ on the straight line L2.

  Next, the preliminary sliding nozzle 3A is slid in the second direction A2 by the third driving means 8A and accommodated in the empty sliding nozzle holding member 2 on the straight line L2a, and the above operation is repeated thereafter.

  The sliding nozzle device according to the present embodiment includes a plurality of preliminary sliding nozzles 3A and 3B that are slidably arranged along the second direction A2, and a sliding nozzle holding member that slides them along the second direction A2. 3 is provided with the third drive means 8A and 8B, so that even if the sliding nozzle holding member 2 runs out of sliding nozzles, it can be quickly replaced with a preliminary sliding nozzle, and the number of sliding nozzle replenishments can be reduced. .

1 ... Base plate 1a ... Through hole 2 ... Sliding nozzle holding member 3 ... ··········································································· Nozzle holes 3A, 3B・ First driving means 5... Second driving means 8A, 8B... Third driving means
A1 ... 1st direction
A2 ... 2nd direction

Claims (2)

A sliding nozzle device for discharging molten metal from a molten metal outlet hole at the bottom of the molten metal container,
A base plate provided on the bottom side of the molten metal container and provided with a through hole communicating with the molten metal outflow hole;
A plurality of sliding nozzle holding members arranged to be slidable along the first direction on the lower surface side of the base plate;
A sliding nozzle accommodated in the plurality of sliding nozzle holding members so as to be slidable along a second direction intersecting the first direction;
First driving means for sliding the plurality of sliding nozzle holding members along the first direction;
A sliding nozzle device, comprising: a second drive unit that slides the sliding nozzle along the second direction and aligns the nozzle hole with a position communicating with the through hole of the base plate. A plurality of preliminary sliding nozzles slidably disposed along the second direction on the lower surface side of the base plate;
Sliding nozzle device according to claim 1 having a third drive means for accommodating the sliding nozzle holding member is slid along the plurality of preliminary sliding nozzle in the second direction.

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