JP2013220468A - Mold varying device for continuous casting equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mold varying device for continuous casting equipment capable of reducing steps of short side alignment work and remarkably reducing a mold replacement time.SOLUTION: Respective links 53, 55, 57 are swingably coupled to a fixed fulcrum 52 disposed on a base, a first moving fulcrum 54 disposed on a support member 30 supporting a short side mold member, and a second moving fulcrum 56 disposed on a movable side long side mold member 41, a leading end of the link 55 is swingably coupled to a third moving fulcrum 58 of the link 53, and a leading end of the link 57 is swingably coupled to a fourth moving fulcrum 59 of the link 53. A distance between the fixed fulcrum 52 and the third moving fulcrum 58 is 1/2 of a distance between it and the fourth moving fulcrum 59. Thus, when the movable side long side mold member 41 moves, the support member 30 moves by 1/2 of it in conjunction and alignment is automatically performed.

Description

  The present invention relates to a mold variable device for changing the cross-sectional size of a slab (thickness of a slab) in a continuous casting facility, and in particular, the support position of a short side mold in the width direction (slab thickness). The present invention relates to a mold variable device for continuous casting equipment that can be maintained in the center of the vertical direction.

  Molten steel smelted in the converter is stored in a ladle, transported to a continuous casting facility, poured into a mold of the continuous casting facility, and cooled by this mold to form a solidified shell in the periphery. In the state containing molten steel, the unsolidified slab is drawn downward from the lower end of the mold and supported by a roll zone consisting of a large number of rolls, and further cooled by spraying cooling water from a spray nozzle. After that, it is cut at appropriate intervals in the longitudinal direction to form slabs. Thus, in a continuous casting facility, molten steel is continuously poured into a mold, and this molten steel is continuously solidified to form a cast piece.

  In this continuous casting equipment, the mold is usually made of a copper plate, but the slab is usually plate-shaped and the cross section is rectangular, so the mold is in contact with the long side surface of the slab. It is composed of a long side copper plate that cools this, and a short side copper plate that contacts and cools the short side surface of the slab, and arranges a pair of long side copper plates facing each other, and these A pair of short-side copper plates are arranged to face each other between the long-side copper plates, and molten steel is injected into a region surrounded by the long-side copper plates and the short-side copper plates so as to cast a slab having a rectangular section. It has become.

  And in the conventional mold, according to the cross-sectional shape of the cast piece used as a cast iron, the short side copper plate can be replaced with one having a different short side length (Patent Documents 1 and 2). That is, in these prior arts, the thickness of the slab can be changed by changing the interval between the long side copper plates and exchanging the copper plates having different short side lengths between the long side copper plates.

  FIG. 9 is a plan view showing a conventional process for replacing the short-side copper plate of the mold in order to change the thickness of the slab. As shown in FIG. 9 (a), a pair of long side copper plates 1a, 1b are arranged in parallel to face each other, and a pair of short side copper plates 2a, 2b are parallel between these long side copper plates 1a, 1b. Opposed. Behind the long side copper plates 1a and 1b, long side water boxes 3a and 3b to which cooling water is supplied are fixed in contact with the long side copper plates 1a and 1b, respectively. It is designed to cool. Also, behind the short side copper plates 2a and 2b, short side water boxes 4a and 4b to which cooling water is respectively supplied are fixed in contact with the short side copper plates 2a and 2b, respectively. 2b is cooled. Further, behind each short side water box 4a, 4b, spindles 6a, 6b are horizontally installed with their rods facing the short side water boxes 4a, 4b, respectively, and are provided at the tips of the rods of the spindles 6a, 6b. The support plates 5a and 5b thus connected to the short-side water boxes 4a and 4b, respectively. Accordingly, by moving the rods of the spindles 6a and 6b to advancing and retracting, the position of the short side copper plates 2a and 2b in the slab width direction can be adjusted, the distance between the short side copper plates can be changed, and the slab width can be changed. . Further, by retracting the rods of the spindles 6a and 6b, the short piece copper plates 2a and 2b and the short piece water boxes 5a and 5b can be exchanged. The long side copper plate 1b and the long side water box 3b are fixed (F (Fixed) side mold), and the long side copper plate 1a and the long side water box 3a are close to the long side copper plate 1a and the long side water box 3a. It is movable to be separated (L (Loose) side mold). In FIG. 9A, the thickness of the slab is t, and the center of the thickness is supported by the support plates 5a and 5b of the spindles 6a and 6b.

  On the other hand, when changing the thickness of the mold in order to cast a thicker slab in the casting process, first, as shown in FIG. 9B, the long side copper plate 1a and the long side water box 3a on the L side. Are retracted from the long side copper plate 1b and the long side water box 3b on the F side, the short side water boxes 4a and 4b are removed from the support plates 5a and 5b, and the short side copper plates 7a and 7b having a long length in the slab thickness direction are Replace with short-side water box 8a, 8b. In this state, since the position of the spindle 6a, 6b for changing the mold width (for changing the slab width) is not changed, the center of the support position of the support plates 5a, 5b for supporting the short-side water boxes 8a, 8b is The distance between the F side long side copper plate 1b remains t / 2, the distance between the L side long side copper plate 1a becomes Tt / 2, and the center of the support position is biased toward the F side. doing. For this reason, when the molten steel is cast into the mold, the static pressure of the molten steel is such that the portion on the L side of the short side copper plates 7a, 7b is centered on the support position center biased to the F side than the portion on the F side. It acts on the short side copper plates 7a and 7b in the direction of wide opening. Then, due to the eccentric load due to the center offset, elastic deformation of the width change propulsion spindles 6a and 6b occurs, and the short side copper plates 7a and 7b are inclined in opposite directions in a plan view, and the short side copper plates 7a and 7b. May bite into the surfaces of the long side copper plates 1a and 1b, and the surfaces of the long side copper plates 1a and 1b may be wrinkled.

  For this reason, when the mold thickness is changed, it is necessary to perform short-side alignment as shown in FIG. That is, as shown in FIG. 9C, after the L-side long copper plate 1a and the long-side water box 3a are retracted to widen the distance between the long-side copper plates 1a and 1b, the F-side long-side copper plate 1b The distance change spindles 6a and 6b are moved to a position where the distance of T is T / 2, and the positions where the support plates 5a and 5b support the short-side water boxes 5a and 5b and the positions of the spindles 6a and 6b are changed to the short-side copper plates 7a and 7b. Align with the center of. In this state, the long side copper plate 1a is moved toward the long side copper plate 1b, the short side copper plates 7a and 7b are sandwiched between the long side copper plates 1a and 1b, and the long side copper plates 1a and 1b and the short side copper plates 7a and 7b are interposed. Assemble a mold having a rectangular casting space. Thereby, the mold with which the short side alignment was taken can be obtained.

Japanese Utility Model Publication No. 6-5742 JP-A-5-245590

  However, the mold short-side aligning device of this prior art requires a short-side aligning drive device including a screw jack, a motor, a speed reducer, a position detector, etc. as its dedicated drive device, and the equipment is expensive. There is a problem that there is.

  In addition, the series of work steps for changing the mold thickness requires replacement of the short-side copper plate and short-side water box and alignment work in series, and there is a problem that the mold thickness change work time is long. In the continuous casting process, while the slab is present in the continuous casting facility, the casting of molten steel (drawing of the slab) is temporarily stopped, the short side copper plate and the short side water box are replaced, and the alignment work is performed. However, the continuous casting process has been operating for 24 hours, and the longer the stoppage is made, the worse the productivity. The short side aligning work normally requires about 10 minutes, and even shortening it is not effective for shortening the mold changing work time alone.

  The present invention has been made in view of such problems, and it is an object of the present invention to provide a mold variable device for a continuous casting facility that can reduce the short side alignment work process and can significantly shorten the mold changing work time.

The mold variable device of the continuous casting equipment according to the present invention,
A fixed-side long side mold member that cools one surface of the slab long side,
A movable long side mold member that is disposed opposite to the fixed side long side mold member and cools the other side of the slab long side,
Two short-side mold members that are disposed so as to face each other between the fixed-side long-side mold member and the movable-side long-side mold member and cool two surfaces on the short side of the slab,
Two sets of short-side drive members that are installed for each short-side mold member, support the back portion of the short-side mold member in the facing direction, and move the short-side mold member in the facing direction and in the opposite direction;
A long-side drive member that moves the movable-side long-side mold member in a direction facing the fixed-side long-side mold member and in the opposite direction;
A support member for supporting the short side drive member;
A guide member that guides the support member so as to be movable in the opposing direction of the fixed-side long-side mold member and the movable-side long-side mold member;
A plurality of link members are connected, and the support member is moved so as to be a half of the movement amount of the movable side long side mold member in conjunction with the movement of the movable side long side mold member. A link mechanism
It is characterized by having.

In the present invention, the link mechanism is, for example,
A first link swingably connected to a fixed fulcrum that does not move with a horizontal direction perpendicular to the moving direction of the support member as a rotation axis;
A second link provided on the support member and swingably coupled to a first movement fulcrum having a direction parallel to the rotation axis of the fixed fulcrum;
A third link provided on the movable long-side mold member and swingably coupled to a second movement fulcrum having a direction parallel to the rotation axis of the fixed fulcrum;
And connecting the first link to the third link to move the support member by a movement amount related to the movement amount of the movable long side mold member in conjunction with the movement of the movable long side mold member. It can be constituted as follows.

In the mold variable device of this continuous casting equipment, for example,
The tip of the second link is rotatably connected to a third movement fulcrum of the first link, and the tip of the third link is rotatably connected to a fourth movement fulcrum of the first link, and the fourth movement. The length between the fulcrum and the fixed fulcrum may be configured to be twice the length between the third movement fulcrum and the fixed fulcrum.

In the present invention, for example,
Each of the first to third links is a fifth fulcrum, the first link and the third link cannot rotate with each other, and the second link is connected to the first link and the third link. And the length between the fifth movement fulcrum and the fixed fulcrum is the same as the length between the fifth movement fulcrum and the second movement fulcrum. The 5 movement fulcrum can be configured to be movable in a direction toward the fixed fulcrum.

Furthermore, in the present invention, for example,
The fixed-side long-side mold member includes a fixed-side long-side copper plate and a fixed-side long-side water box that is installed behind the fixed-side long-side copper plate and cools the fixed-side long-side copper plate. It consists of a side copper plate and a movable side long side water box that is installed behind it to cool the movable side long side copper plate, and the short side mold member is installed behind the short side copper plate and cools the short side copper plate It consists of a short side water box.

  In the present invention, when the movable side long side mold member is moved in the direction facing the fixed side long side mold member in order to replace the short side mold member, the movable side long side mold member is moved by the link mechanism. In conjunction with this, the short-side drive member that supports the short-side mold member also moves by a movement amount related to the movement amount of the movable-side long-side mold member, and therefore the alignment of the short-side drive member that supports the short-side mold member The process can be eliminated, the time for replacing the short side mold member can be remarkably shortened, and the productivity can be improved.

  Moreover, since the link mechanism can be provided in the slab moving direction (vertical direction) by configuring the link mechanism as in claim 2, space saving of the link mechanism around the mold can be achieved. This is advantageous when the present invention is applied to a continuous casting facility having a plurality of lanes (casting lines).

It is a figure which shows the mold variable apparatus of the continuous casting installation which concerns on embodiment of this invention, (a) is a top view, (b) is a front view, (c) is a left view. Similarly, it is the front enlarged view. (A), (b) is a top view which shows the part, and is a figure which shows operation | movement of a long side mold member. It is sectional drawing which shows a slide key and a keyway. It is a perspective view which shows the shape of a base typically. (A), (b) is the back view and left view of a supporting member, respectively. It is a schematic diagram which shows operation | movement of this embodiment. It is a schematic diagram which shows other embodiment of this invention. (A) thru | or (c) is a top view which shows the replacement | exchange process of the conventional short side mold member.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the accompanying drawings. FIG. 1 is a view showing a mold variable device of a continuous casting facility according to an embodiment of the present invention, wherein (a) is a plan view showing a part thereof, (b) is a front view, and (c) is a part thereof. FIG. 2 is a left side view, FIG. 2 is an enlarged front view of the apparatus according to the present embodiment, and FIGS. 3A and 3B are plan views showing the operation of the long side mold member. . As shown in FIGS. 1A and 3, a long side mold member 42 on the F side (fixed side) and a long side mold member 41 on the L side (movable side) are disposed to face each other, and the short side is interposed therebetween. Spindles 61, 62, and 63 are disposed to support the mold member so as to be movable in the slab width direction. As shown in FIG. 3, the F-side long-side mold member 42 is composed of a long-side copper plate 1b and a long-side water box 3b, and the L-side long-side mold member 41 is composed of a long-side copper plate 1a and a long-side water box 3a. Composed. The long-side copper plate 1a and the long-side water box 3a are driven by a mold thickness (slab thickness) change driving device 14 so as to move in a direction opposite to the long-side copper plates 1a and 1b.

  As shown in FIG. 3 (a), both end portions 3c in the slab width direction of the L-side long water box 3a are movably supported on side portions 44a of the base 40 in FIG. Both end portions 3d in the slab width direction of the side long side water box 3b are fixed on the side portions 44b of the base 40 in FIG. And the spindles 6a and 6b are arrange | positioned in the area | region except the mold part between the long side water box 3b and the long side water box 3a. The spindles 6a and 6b are rotationally driven by an appropriate driving device to approach or separate the short side copper plates 2a and 2b and the short side water boxes 4a and 4b attached to the support plates 5a and 5b at the tips of the rods. Move in the direction. Thereby, the space | interval between the short side copper plates 2a and 2b is changed, and the slab width | variety made into a cast iron is changed. On the other hand, the spindles 6a and 6b are supported so as to be movable in the slab thickness direction (mold thickness direction), that is, in the opposing direction of the long-side copper plates 1a and 1b, as described later. The long-side water box 3b and the long-side water box 3a are connected by rods 15 in the vicinity of both outer sides of the long-side copper plates 1a and 1b, respectively, and provided at the end of the rod 15 on the long-side water box 3a side. By the clamp spring 16, the long water box 3a is locked with an elastic force applied in a direction toward the long water box 3b. A mold thickness (slab thickness) changing drive device 14 is provided at the end of the rod 15 on the long side water box 3b side, and the protruding length of the rod 15 can be changed by this drive device 14. Thereby, as shown in FIG.3 (b), the space | interval (thickness of slab) between the long side copper plates 1a and 1b can be changed.

  As shown in FIGS. 1B and 1C, the spindles for changing the slab width by moving the short side copper plate and the short side water box in the slab width direction are the upper spindle 61 and the lower spindle 62. The support plate 5b to which the short-side water box 4b is attached is commonly connected to the clevis 6b2 at the tip of the rod of each spindle 61, 62 by the connecting pin 6b3. The two upper and lower spindles 61 and 62 are supported in common by the support members 30 and 31 at two positions in the longitudinal direction of the spindles 61 and 62, respectively. 1 to 3 corresponds to the spindle 6b in FIG. 9, and the spindle 63 shown in FIG. 3 corresponds to the spindle 6a in FIG. A lower spindle similar to the spindle 62 is disposed below the spindle 63, but is not shown. However, like the spindles 61 and 62, the spindle 63 and the like are also supported by the support members 30 and 31 in common. In this way, the pair of opposing short-side mold members are connected together to the upper and lower two-stage spindles 61 and 62 respectively supported by the two support members 30 and 31 at two points in the longitudinal direction. While being supported by the spindles 61 and 62, it is movable in the slab thickness direction. As described above, the short side copper plate and the short side water box are supported by the upper and lower two stages of the spindles 61 and 62 so as to be movable in the slab thickness direction. This is because the short-side copper plate and the short-side water box to which the molten steel static pressure is applied are supported and held at a predetermined position with high accuracy. The upper and lower two-stage spindles 61 and 62 are supported at two points in the longitudinal direction by the support members 30 and 31 so that the axial direction of the spindles 61 and 62 does not fluctuate due to the molten steel static pressure. It is to do. However, the present invention is not limited to this, and at least one spindle and one support member are disposed on both sides in the slab width direction so as to support the short-side copper plate and the short-side water box, respectively. Good.

  The F-side long side mold member 42 is fixedly installed on the base 40, and the L-side long side mold member 41 is installed on the base 40 so as to be movable in the slab thickness direction. As schematically shown in FIG. 5, the base 40 has a central portion 45 with a high height when viewed from the front, and side portions 44 a and 44 b on both sides thereof have a low height. The long side mold member 42 on the fixed side (F side) (both end portions 3d of the water box 3b) is fixed on the side portion 44b. The movable side (L side) long side mold member 41 (both end portions 3c of the water box 3a) can move on the side portion 44a in the longitudinal direction of the base 40 (the slab thickness direction). It has become. The base 40 is provided with a pair of holes 46 penetrating the base 40 in the width direction of the base 40 (width direction of the slab) at the upper and lower stages of the central portion 45, and these holes 46 has a flat shape extending in the moving direction of the long side mold member 41 on the L side. In addition, a long strip-like slide key 32 extending in the horizontal direction (the thickness direction of the slab) is secured by a bolt 38 at an appropriate position between a pair of upper and lower holes 46 on the surface side surface of the base 40. It is fixed. In the hole 46, upper and lower two-stage spindles 61 and 62 that support the short-side mold member on one end side in the slab width direction are arranged so as to come out from the surface of the base 40 to the back surface. . These spindles 61 and 62 can move in the hole 46 in the horizontal direction and in the thickness direction of the slab as indicated by arrows in FIG. A gap is provided between the spindles 61 and 62 and the hole 46 so that the movement of the spindles 61 and 62 is not hindered. As shown in FIG. 1A, the spindles 61 and 62 are commonly supported by the support member 30 on the front surface side of the base 40, and are commonly supported by the support member 31 on the back surface side of the base 40. The above description is about one end in the slab width direction (end on the short side copper plate 2b side), and the spindle 61 corresponds to the spindle 6b in FIG. 9, but the other in the slab width direction. Similarly, for the end portion (end portion on the short side copper plate 2a side), a base is installed, and the spindle 63 (corresponding to the spindle 6a) on the short side copper plate 2a side, etc. Is supported so as to be movable. Therefore, only the spindle support mechanism on the short side copper plate 2b side will be described below. The long side mold members 41 and 42 are supported by the side portions 44a and 44b of the base 40 at both ends in the longitudinal direction (slab width direction). The middle part of the direction extends in the vertical direction between the two bases 40 with the same length as the support member 30 that supports the short-side mold member, and the long-side copper plate is the same as the short-side copper plate. Has a height of

  6A is a back view of the support member 30 viewed from the base 40 side, and FIG. 6B is a side view of the support member 30 viewed from the side portion 44a side to the side portion 44b side in FIG. (Left side view). The support member 30 is assembled by fixing two plate members with bolts 36. In this assembled state, a circular hole 34 through which the spindle 61 is inserted is formed in the upper half, and the lower half is formed. A circular hole 35 through which the spindle 62 is inserted is formed. The positions of these holes 34 and 35 are aligned with the positions of the holes 46 of the base 40 shown in FIG. 5. Further, the positions of the support members 30 aligned with the slide keys 32 of the base 40 are A key groove 37 into which the slide key 32 is fitted is formed. That is, as shown in FIG. 4, the support member 30 that supports the spindles 61 and 62 has the slide key 32 that is fixed to the base 40 by the bolts 38 fitted in the key groove 37, thereby sliding the slide member 32. The upper and lower surfaces 39 of the key 32 can be slid while being guided in the slab thickness direction (in the direction of the arrow in FIG. 5) with the upper and lower surfaces 39 as guide surfaces. A load is supported. A key groove is also formed on the surface of the support member 31 facing the support member 30, and a slide key is also provided on the surface of the base 40 on the support member 31 side. Similarly, the support member 31 is also the base 40. It is possible to move in the slab thickness direction (opposite direction of the long side copper plate) while carrying a load.

  Thus, in this embodiment, the link mechanism 50 is provided between the support member 30 that supports the short-side mold member (short-side copper plate and short-side water box) and the L-side long-side mold member 41. . A similar link mechanism is also provided between the other support member 31 and the L-side long side mold member 41. The link mechanism on the support member 31 side is basically the same as the link mechanism on the support member 30 side. Therefore, only the link mechanism on the support member 30 side will be described below. As shown in FIG. 2, the link mechanism 50 has a base 51 fixed to the base 40. The base 51, the support member 30, and the F-side long side mold member 41 are all fixed fulcrums 52 that are perpendicular to the movement direction of the support member 30 and have the horizontal direction as the rotation axis. A first movement fulcrum 54 and a second movement fulcrum 56 are provided. Since the fixed fulcrum 52 is provided on the base 51, it does not move. The first movement fulcrum 54 moves with the movement of the support member 30, and the second movement fulcrum 56 moves with the F-side long side mold 41. The link 53 is swingably connected to the fixed fulcrum 52, the link 55 is swingably connected to the first moving fulcrum 54, and the link 57 is swingably connected to the second moving fulcrum 56. Yes. The tip of the link 55 is swingably connected to a third movement fulcrum 58 provided on the link 53, and the tip of the link 57 is swingably connected to a fourth movement fulcrum 59 provided on the link 53. Has been. The length between the fixed fulcrum 52 and the fourth movement fulcrum 59 is twice the length between the fixed fulcrum 52 and the third movement fulcrum 58. In the illustrated example, the second movement fulcrum 54 is at the same height as the slide key 32 that movably supports the support member 30, but the second movement fulcrum 54 is not necessarily provided in this way.

  Next, the operation of the mold variable device of the present embodiment configured as described above will be described. Molten steel is poured into a rectangular region in plan view surrounded by the long side mold members 41, 42 and the short side mold member, and the molten steel is cooled by the long side copper plate and the short side copper plate that are cooled by the water box, and the solidified shell. After the slab is formed, the slab is started to be drawn, and thereafter, the slab is continuously drawn and continuously cast. After that, when changing the width of the slab during the continuous casting process, the drawing of the slab is temporarily stopped, the clamp spring 16 is loosened, the clamping force of the short side copper plate by the long side copper plate is loosened, and the spindle By driving 61, 62, 63, etc., the position between the short side copper plates 2a, 2b is changed, and the width of the slab is changed. On the other hand, when changing the thickness of the slab, it is necessary to replace the short-side mold member. Therefore, the L-side long-side mold 41 is shown in FIG. Move to the left as shown in the drawing arrow. Then, the link 57 connected to the second movement fulcrum 56 of the L-side long side mold member 41 causes the link 53 to swing counterclockwise via the fourth movement fulcrum 59. As a result, the link 55 connected to the link 53 via the third movement fulcrum 58 pulls the support member 30 leftward (in the direction of the white arrow) via the first movement fulcrum 54. Since the support member 30 and the like are supported by the slide key 32 and the like of the base 40 so as to be movable in the slab thickness direction, the support member 30 and the like are interlocked with the movement of the L-side long side mold member 41, Can move. Accordingly, the spindles 61 and 62 supported by the support member 30 and the like, and the short-side mold member supported by the spindles 61 and 62 and the like are similarly linked to the movement of the L-side long-side mold member 41, Can move. At this time, since the length between the fourth movement fulcrum 59 and the fixed fulcrum 52 is twice the length between the third movement fulcrum 58 and the fixed fulcrum 52, the support member 30 and the like and the short-side mold The movement distance of the member is ½ of the movement distance of the L-side long side mold member 41.

  Therefore, when the L-side long-side mold member 41 is moved in the direction of the white arrow for the replacement of the short-side mold member, the spindles 61 and 62 are connected to the long-side mold member 41 and the long-side mold before starting the movement. When located at the center between the member 42, the spindles 61 and 62 are located at the center between the long side mold member 41 and the long side mold member 42 even after movement. That is, when the distance between the long side mold members 41 and 42 is D before the movement starts, when the spindles 61 and 62 are located at the center between the long side mold member 41 and the long side mold member 42 The distance in the slab thickness direction between the center of the spindles 61 and 62 and the surface of the L-side long side mold member 41 is D / 2. From this state, when the L-side long side member 41 moves by d in the direction of the white arrow, as described above, the support member 30 and thus the spindles 61 and 62 are moved in the direction of the white arrow by the link mechanism 50. Move by two. Therefore, after movement, the distance between the long side mold members 41 and 42 is D + d, and the distance in the slab thickness direction between the center of the spindles 61 and 62 and the surface of the L side long side mold member 41 is D / 2 + d / 2 = (D + d) / 2, and after the movement, the spindles 61 and 62 are located at the center position between the long side mold members 41 and 42 in the slab thickness direction. Therefore, in this state, the short side mold member may be replaced. After the replacement, if the L side long side mold member 41 is moved toward the F side long side mold member 42, the L side long side mold member 41 is replaced. The short-side mold member also returns by a half of the movement amount of the contact between the pair of long-side copper plates and the pair of short-side copper plates therebetween, thereby completing the replacement of the short-side mold members.

  In the link mechanism 50, since the link 53 swings around the fixed fulcrum 52, the movement distance of the second movement fulcrum 56 is strictly two times the movement distance of the first movement fulcrum 54. Absent. FIG. 7 is a schematic diagram showing the link mechanism 50. In FIG. 7, the support member 30 that supports the spindles 61 and 62 is positioned between the F-side long water box 42 a and the L-side long water box 41 a in the slab thickness direction. A first moving fulcrum 54 (E) is provided on the connecting portion 30 a provided on the side surface of the support member 30, and a second moving fulcrum 56 (C) is provided on the connecting portion 41 b provided on the lower surface of the L-side long water box 41 a. ) Is provided. The length between the fourth movement fulcrum 59 (B) and the fixed fulcrum 52 (A) is L, the length between the third movement fulcrum 58 (D) and the fixed fulcrum A is L / 2, and L When the movement amount of the side long side water box 41a is W, the movement amount Z of the support member 30 is approximately Z = W / 2.

Next, the error of the movement amount Z of the support member 30 is estimated. Before the movement, the link 53 is vertical, the link 57 is horizontal, the length between the second movement fulcrum C and the fourth movement fulcrum B is L3, and the link 55 is horizontal and It is assumed that the length between the first movement fulcrum E and the third movement fulcrum D is L4. When the link 53 is inclined as shown by a broken line in FIG. 7, the horizontal movement distance X of the fourth movement fulcrum B is expressed by the following mathematical formula.
X = W−L3 + √ (L3 ² −h ² ) = W−L3 + L3√ (1− (h / L3) ²
Since h is very small with respect to L3, the following mathematical expression is approximately obtained.
X = W
h = L−√ (L ² −W ² )
When the link 57 is tilted from the horizontal, the difference ΔL3 from the horizontal projection length of the tilted link 57 is expressed by the following equation.
ΔL3 = L3−√ (L3 ² −h ² )
Similarly, the difference ΔL4 from the horizontal projection length of the inclined link 55 is expressed by the following equation.
ΔL4 = L4−√ (L4 ² −h1 ² )
The error ΔL3 is half of ΔL3 / 2 from the link length ratio, which affects the error of the movement amount of the support member 30. Therefore, the error ΔZ of the movement amount Z of the support member 30 and thus the first movement fulcrum 54 is expressed by the following mathematical formula.
ΔZ = ΔL3 / 2 + ΔL4
The error ΔZ in the case of the mold dimensions shown in Table 1 below was calculated from this equation. The unit is mm.

  As shown in Table 1, even if the long-side mold member moves by W = 100 mm, the error of the movement amount Z of the short-side mold member is 0.6011 mm. For example, there is a gap of 2-3 mm on one side between the side surface of the clevis 6b2 of the spindle 6b and the connecting portion 5b1 of the support plate 5b to which the short side water box 4b is attached, and an error of about 0.6 mm is the size of this gap. To be absorbed. Note that the error in Table 1 is calculated using an approximate expression as described above, but this error becomes even smaller when calculated strictly.

  Thus, in this embodiment, when the L-side long-side mold member 41 moves, the spindles 61 and 62 that hold the short-side mold member are also moved by the link mechanism when the L-side long-side mold member 41 moves. Is moved in the same direction as the L-side long-side mold member 41 by ½. That is, the spindles 61 and 62 that hold the short-side mold member move in conjunction with the L-side long-side mold member 41. Therefore, in the present embodiment, the spindle for holding the short-side mold member is always located at the center between the long-side mold members, so that the conventional process for short-side alignment is not necessary. For this reason, the time required for replacement of the short side mold member can be remarkably shortened, and the productivity can be remarkably increased. In FIG. 2, the height position of the slide key 32 is not on the center between the spindles 61 and 62 but on the spindle 62 side. However, the height positions of the slide key 32 and the key groove are arbitrary. is there.

  Next, another embodiment of the present invention will be described with reference to FIG. In the present embodiment, the configuration of the link mechanism 70 is different from that shown in FIG. 7, and the other configurations are the same as those shown in FIGS. In this embodiment, a link 73 swingably connected to a fixed fulcrum 72 (A) provided on a base 71 fixed to a base 40 (see FIG. 2), and a lower end of an L-side long water box 41a. A link 77 slidably connected to a second movement fulcrum 76 (B) provided in the connecting portion 41 b is connected by a third movement fulcrum 78 (D). The third movement fulcrum 78 (D) is mutually non-rotatable. Therefore, the link 73 and the link 77 are fixed on a straight line. On the other hand, a link 75 is connected to the first movement fulcrum 74 (E) provided in the connecting portion 30 a on the side surface of the support member 30, and the link 75 is rotatable to the third movement fulcrum 78 (D). It is connected to.

  As shown in FIG. 8 (b), a guide portion 82 is formed in the connecting portion 41b of the L-side long water box 41a, and the slide block 81 is moved by the guide portion 82 with respect to the moving direction of the long side water box 41a. It is supported so as to be movable vertically downward. The slide block 81 is provided with a second movement fulcrum 76 (B). Therefore, the second movement fulcrum 76 (B) moves in the horizontal direction along with the movement of the L-side long water box 41a and in the vertical direction. Also move.

  Therefore, as shown in FIG. 8A, when the L-side long water box 41a moves in the direction indicated by the white arrow, the links 73 and 77 are inclined as indicated by the broken line, and the third movement fulcrum 78 ( Since D) moves by Y at a horizontal distance, the links 73 and 77 pull the first moving fulcrum 74 (E) through the link 75 in the direction of the white arrow, and thus support the spindles 61 and 62. The support member 30 also moves by Z in the direction of the white arrow. At this time, if the links 73 and 77 are tilted from the state in the vertical direction, the distance between the third movement fulcrum 78 (D) and the connecting portion 41 b increases, but the change in the distance is caused by the second movement fulcrum 76. (B) is absorbed by moving vertically downward along the guide portion 82, and the connection of the second movement fulcrum 76 (B) to the connecting portion 41b is maintained.

  In the present embodiment, although the accuracy is somewhat lower than in the embodiments shown in FIGS. 1 to 7, the movement amount of the support member 30 that supports the spindles 61 and 62 is similarly set to the long side on the L side. The amount of movement of the mold member 41 can be halved. Therefore, also in this embodiment, the alignment process can be omitted, the time required for replacement of the short side mold member can be remarkably shortened, and the productivity can be improved.

  In the present embodiment, the link 73 and the link 77 are non-rotatably connected by the second moving link 78. This is because the fixed fulcrum 72 and the second moving fulcrum 76 are connected by one link. Of course, the third movement fulcrum 78 may be provided at the center of the link. Such a configuration also belongs to the technical scope of the present invention.

  According to the present invention, when replacing the short side mold member for changing the thickness of the slab, the short side driving member for supporting the short side mold member is interlocked with the movement of the L side long side mold member. Since the L-side long side mold member can be moved in accordance with the amount of movement, the time for stopping the drawing of the slab can be remarkably shortened. For this reason, this invention makes a great contribution to the improvement of productivity in a continuous casting facility.

1a, 1b: Long side copper plates 2a, 2b, 7a, 7b: Short side copper plates 3a, 3b, 41a, 42a: Long side water boxes 4a, 4b, 8a, 8b: Short side water boxes 5a, 5b: Support plates 6a, 6b, 61, 62: Spindle 30, 31: Support member 32: Slide key 37: Key groove 40: Base 41, 42: Long side mold member 50: Link mechanism 53, 55, 57, 73, 75, 77: Link 52, 72: Fixed fulcrum 54, 56, 58, 59, 74, 76, 78: Moving fulcrum

Claims (5)

A fixed-side long side mold member that cools one surface of the slab long side,
A movable long side mold member that is disposed opposite to the fixed side long side mold member and cools the other side of the slab long side,
Two short-side mold members that are disposed so as to face each other between the fixed-side long-side mold member and the movable-side long-side mold member and cool two surfaces on the short side of the slab,
Two sets of short-side drive members that are installed for each short-side mold member, support the back portion of the short-side mold member in the facing direction, and move the short-side mold member in the facing direction and in the opposite direction;
A long-side drive member that moves the movable-side long-side mold member in a direction facing the fixed-side long-side mold member and in the opposite direction;
A support member for supporting the short side drive member;
A guide member that guides the support member so as to be movable in the opposing direction of the fixed-side long-side mold member and the movable-side long-side mold member;
A plurality of link members are connected, and the support member is moved so as to be a half of the movement amount of the movable side long side mold member in conjunction with the movement of the movable side long side mold member. A link mechanism
A mold variable device for continuous casting equipment, comprising: The link mechanism is
A first link swingably connected to a fixed fulcrum that does not move with a horizontal direction perpendicular to the moving direction of the support member as a rotation axis;
A second link provided on the support member and swingably coupled to a first movement fulcrum having a direction parallel to the rotation axis of the fixed fulcrum;
A third link provided on the movable long-side mold member and swingably coupled to a second movement fulcrum having a direction parallel to the rotation axis of the fixed fulcrum;
And connecting the first link to the third link to move the support member by a movement amount related to the movement amount of the movable long side mold member in conjunction with the movement of the movable long side mold member. The mold variable device of the continuous casting equipment according to claim 1. The tip of the second link is rotatably connected to a third movement fulcrum of the first link, and the tip of the third link is rotatably connected to a fourth movement fulcrum of the first link, and the fourth movement. 3. The mold variable of the continuous casting equipment according to claim 2, wherein a length between the fulcrum and the fixed fulcrum is twice as long as the length between the third moving fulcrum and the fixed fulcrum. apparatus. Each of the first to third links is a fifth fulcrum, the first link and the third link cannot rotate with each other, and the second link is connected to the first link and the third link. And the length between the fifth movement fulcrum and the fixed fulcrum is the same as the length between the fifth movement fulcrum and the second movement fulcrum. 5. The mold variable device for continuous casting equipment according to claim 2, wherein the five moving fulcrums are movable in a direction toward the fixed fulcrum. The fixed-side long-side mold member includes a fixed-side long-side copper plate and a fixed-side long-side water box that is installed behind the fixed-side long-side copper plate and cools the fixed-side long-side copper plate. It consists of a side copper plate and a movable side long side water box that is installed behind it to cool the movable side long side copper plate, and the short side mold member is installed behind the short side copper plate and cools the short side copper plate 5. The mold variable device for continuous casting equipment according to claim 1, comprising a short-side water box.

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