CN115301935A - Tundish with filter module - Google Patents
Tundish with filter module Download PDFInfo
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- CN115301935A CN115301935A CN202210473096.8A CN202210473096A CN115301935A CN 115301935 A CN115301935 A CN 115301935A CN 202210473096 A CN202210473096 A CN 202210473096A CN 115301935 A CN115301935 A CN 115301935A
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- tundish
- cavity
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- 239000002184 metal Substances 0.000 claims abstract description 107
- 229910052751 metal Inorganic materials 0.000 claims abstract description 107
- 238000001914 filtration Methods 0.000 claims abstract description 40
- 230000005484 gravity Effects 0.000 claims description 7
- 238000005058 metal casting Methods 0.000 claims description 6
- 238000007599 discharging Methods 0.000 claims description 2
- 238000002360 preparation method Methods 0.000 claims 1
- 239000007787 solid Substances 0.000 description 15
- 238000005266 casting Methods 0.000 description 11
- 239000012535 impurity Substances 0.000 description 10
- 230000007547 defect Effects 0.000 description 8
- 230000007246 mechanism Effects 0.000 description 6
- 239000011819 refractory material Substances 0.000 description 6
- 230000002093 peripheral effect Effects 0.000 description 4
- 230000035699 permeability Effects 0.000 description 4
- 238000000926 separation method Methods 0.000 description 4
- 238000000034 method Methods 0.000 description 3
- 238000011144 upstream manufacturing Methods 0.000 description 3
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- 239000007788 liquid Substances 0.000 description 2
- 230000008569 process Effects 0.000 description 2
- 230000000630 rising effect Effects 0.000 description 2
- 238000007789 sealing Methods 0.000 description 2
- 230000004888 barrier function Effects 0.000 description 1
- 230000015572 biosynthetic process Effects 0.000 description 1
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- 230000002596 correlated effect Effects 0.000 description 1
- 239000000706 filtrate Substances 0.000 description 1
- 150000002739 metals Chemical class 0.000 description 1
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- 239000012465 retentate Substances 0.000 description 1
- 239000002893 slag Substances 0.000 description 1
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D41/00—Casting melt-holding vessels, e.g. ladles, tundishes, cups or the like
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
- B22D11/10—Supplying or treating molten metal
- B22D11/11—Treating the molten metal
- B22D11/116—Refining the metal
- B22D11/119—Refining the metal by filtering
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
- B22D11/10—Supplying or treating molten metal
- B22D11/11—Treating the molten metal
- B22D11/116—Refining the metal
- B22D11/118—Refining the metal by circulating the metal under, over or around weirs
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D41/00—Casting melt-holding vessels, e.g. ladles, tundishes, cups or the like
- B22D41/003—Casting melt-holding vessels, e.g. ladles, tundishes, cups or the like with impact pads
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D41/00—Casting melt-holding vessels, e.g. ladles, tundishes, cups or the like
- B22D41/08—Casting melt-holding vessels, e.g. ladles, tundishes, cups or the like for bottom pouring
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D43/00—Mechanical cleaning, e.g. skimming of molten metals
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D43/00—Mechanical cleaning, e.g. skimming of molten metals
- B22D43/001—Retaining slag during pouring molten metal
- B22D43/004—Retaining slag during pouring molten metal by using filtering means
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Casting Support Devices, Ladles, And Melt Control Thereby (AREA)
- Manufacture And Refinement Of Metals (AREA)
- Separation Using Semi-Permeable Membranes (AREA)
- Extrusion Moulding Of Plastics Or The Like (AREA)
Abstract
A filter module (1) for a filtration system of a tundish (10) comprises a filtration unit (1 f) provided with a channel (1 c) extending from a channel inlet to a channel outlet. The filtration system comprises a wall module (2) comprising walls defining an opening (2 o) extending from the floor (10 f) over an opening height (h 2). A bypass passage (2 b) having a maximum width (t 12) is defined between the wall module (2) and the filter module (1) such that metal melt can only flow from an inlet portion through the channels of the filter unit (1 f) or through the bypass passage (2 b) to the outlet portion. The wall module comprises a wall rail (2L) having a width (t 2L). The filter module (1) further comprises a filter ledge (1L) having a width (t 1L) and being vertically offset with respect to the wall ledge (2L) to form a baffle therewith.
Description
Technical Field
Embodiments of the present invention relate to a continuous metal melt casting tundish provided with a filter unit for removing solid impurities before casting a metal melt into a mould or a tool. In particular, the present invention relates to a tundish comprising a filter module providing two possible paths for the metal melt to flow from an inlet portion of the tundish to an outlet portion comprising a tundish outlet for casting the metal melt into a mould or tool. The metal melt must flow through the filter element, or through a bypass passage designed to facilitate flow through the filter element. However, in case the filter unit is blocked, the flow may continue through the bypass passage.
Background
In the continuous metal forming process, the metal melt is transferred from one metallurgical vessel to another, to a mold or tool. For example, a ladle is filled with a metal melt from a furnace and is driven over a tundish to discharge molten metal from the ladle into the tundish generally through a ladle shroud. The metal melt may then be cast from the tundish outlet through a casting nozzle into a mould or tool for continuous formation of slabs, billets, beams, thin slabs and the like. Under the action of gravity, the metal melt flows out of the ladle into the tundish and then out of the tundish into the mould or tool.
The presence of defects, such as inclusions and impurities, in cast metal parts is a concern. These defects are mainly due to debris and impurities present in the ladle or to wear of the refractory material in the pouring area of the tundish due to impact and friction between the metal melt and the refractory material. It is important to prevent such debris and impurities from reaching the tundish outlet to reduce the number of defects in the cast metal part.
In order to reduce the amount of debris and impurities reaching the tundish outlet, it has been proposed in EP 3470149 to include a baffle module extending across the width of the tundish cavity, which divides the tundish cavity into an inlet portion (defined as the portion of the tundish that receives the metal melt from the ladle) and an outlet portion (defined as the portion of the tundish cavity that includes the tundish outlet). The baffle module is made up of two parallel walls vertically offset with respect to each other, namely a first wall adjacent to the inlet portion defining an opening between the floor of the cavity and the free edge of the first wall, and a second wall extending from the floor to a height higher than the opening defined by the first wall. The metal melt flowing from the inlet portion to the outlet portion is redirected by the baffle module, leaving most of the debris and other solids trapped at the bottom of the second wall. However, the baffle module as described in EP 3470149 primarily traps the heaviest debris and other solids, which cannot follow the tortuous flow provided by the baffle. On the other hand, lighter solids remain suspended and pass through the baffle module to the tundish outlet. Considering that the metal melt has a high density, the solids easily remain suspended and the removal effect of this baffle module is not satisfactory for many applications.
It has also been proposed to incorporate filter modules extending across the width of the tundish cavity for dividing the tundish cavity between the inlet and outlet sections. KR 200303465, for example, describes a tundish comprising a filter module extending over the entire cross section of the tundish cavity, the filter module comprising filter units defining channels through which the metal melt in the inlet portion of the cavity must flow to reach the outlet portion, thereby removing most of the debris and impurities from the metal melt reaching the outlet portion. The use of a filter module allows to significantly reduce the amount of debris and impurities that flow out of the tundish into the tool, but also presents a great risk. Indeed, over time, debris and other solids accumulate on the inlet side of the filter unit, thereby significantly reducing the permeability of the filter unit and increasing the pressure differential (Δ Ρ) required to drive the metal melt through the filter unit. Thus, the level of the metal melt in the inlet portion of the cavity rises relative to the level in the outlet portion until it reaches the top of the filter module to flow across the filter module rather than through the filter unit. If the height of the filter module is close to the height of the tundish, there is a serious risk of metal melt overflowing from the tundish with dire consequences.
To solve the problem of overflow in case of blocked filter units, KR 101853768 describes a filter system comprising a combination of the solutions proposed in EP 3470149 and KR 200303465 discussed above, i.e. by introducing a filter module between the first wall and the second wall of the baffle module of EP 3470149. The filter module is lower than the filter module described in KR 200303465 and has a height similar to the opening height defined by the first wall. The first wall functions to deflect a portion of the metal melt to flow across the filter module and to define a bypass passage between the filter module and the first wall. In this way, in the event of a filter unit being blocked, the metal melt can flow through the bypass passage, across the filter module and the second wall, and thus to the tundish outlet, with some of the heaviest debris and other solids remaining on the filter module and the second wall. The problem with this solution is that even when the filter unit is not blocked, a significant part of the metal melt flows through the bypass channel and not through the filter unit, thereby reducing the effect of the filter system described in KR 101853768.
Accordingly, there is a need for an improved filtration system that overcomes the limitations of the art.
Disclosure of Invention
Embodiments of the present invention relate to a filtration system for effectively removing most of the debris and other solids present in the metal melt flowing through a tundish from an inlet portion to an outlet portion, regardless of their density, and at the same time ensuring a high level of safety without the risk of the metal melt spilling over the tundish edge due to functional impediments to the filtration system. These and other advantages of the present invention will be described in more detail in the sections that follow.
Embodiments of the present invention provide a tundish for continuous metal casting. In various embodiments, the tundish (10) defines a cavity, wherein the cavity has a cavity height (h 10) measured along the vertical axis (Z), a cavity length measured along the longitudinal axis (X), and a cavity width measured along the lateral axis (Y), wherein X ±. Y ×. Z. The cavity includes: an inlet portion (10 i) configured to receive a flow of metal melt (20 m) discharged by gravity from outside the tundish into the cavity of the tundish; an outlet portion (10 o) comprising an outlet (11 o) configured to expel the metal melt from the cavity into a mould; and a filter system separating the inlet portion (10 i) from the outlet portion (10 o) over the entire cavity width. The filter system comprises a filter module (1) extending over the entire cavity width and inside said cavity, wherein the filter module comprises an inlet side facing an inlet portion (10 i) of the tundish and extending from a bottom plate (10 f) of the cavity to a top surface, the shortest distance of which measured along the vertical axis (Z) from the bottom plate being equal to a minimum filter module height (h 1), and wherein the filter module (1) comprises a filter unit (1 f) extending along the vertical axis (Z) over a filter height (hf) and being provided with channels (1 c) extending from channel inlets, i.e. openings at the inlet side facing the inlet portion (10 i) of the tundish, to channel outlets, i.e. openings at the outlet side of the filter module (1) facing the outlet portion and being spaced from the inlet side by a filter depth (tf). The filtration system further comprises a wall module (2) comprising a wall extending over the entire cavity width and inside said cavity and defining one or more openings (2 o) distributed over the width of the wall and over an opening height (h 2) measured from the bottom plate (10 f) along the vertical axis (Z). The filter module (1) is arranged closer to the outlet (11 o) than the wall module (2) and a bypass passage (2 b) having a maximum width (t 12) measured along the longitudinal axis (X) is defined between the wall module (2) and the filter module (1) such that the metal melt can only flow from the inlet portion to the inlet side of the filter module (1) through the one or more openings and from the one or more openings to the outlet portion through a channel flowing through the filter unit (1 f) or the bypass passage (2 b). A wall rail (2L) projects from the wall of the wall module (2) at a wall rail distance (d 2L) (i.e. d2L ≦ h 1) from the floor (10 f) of not more than the minimum filter module height (h 1) and extends towards the inlet side of the filter module (1) without contacting the filter module (1), the wall rail (2L) having a width (t 2L) measured along the longitudinal axis (X), wherein 20mm ≦ t2L ≦ t12. Furthermore, a filter rail (1L) protrudes from the inlet side of the filter module (1) at a filter rail distance (d 1L) (i.e. d1L > h 2) from the floor (10 f) exceeding the opening height (h 2) and is offset (i.e. d1L ≠ d 2L) with respect to the wall rail (2L), the filter rail extending towards the wall module (2) without contacting the wall module or the wall rail, the filter rail (1L) having a width (t 1L) measured along the longitudinal axis (X), wherein 20mm to 1t 12L.
In various embodiments, the ratio (h 2/h 1) of the opening height (h 2) to the filter module height (h 1) is comprised between 20% and 95% (0.2 ≦ h2/h1 ≦ 0.95), preferably between 40% and 80%.
In various embodiments, the ratio of the sum of the widths (t 1L, t 2L) of the filter rail and the wall rail to the maximum width (t 12) of the bypass passage ((t 1L + t 2L)/t 12) is comprised between 20% and 150% (i.e., 0.2 ≦ (t 1L + t 2L)/t 12 ≦ 1.5), preferably between 30% and 120%, more preferably between 50% and 100%.
In various embodiments, the wall module includes a single opening extending from a lower boundary spaced from the floor a distance of 0 to 5% of the cavity height (h 10) to a lower edge of the wall, thereby defining the opening height (h 2) as the distance the floor is spaced from the farthest point of the lower edge. Alternatively, in a second embodiment, the wall module comprises more than one opening, wherein a top opening is defined as the opening having the boundary furthest away from the floor, the boundary furthest away from the floor being spaced from the floor by the opening height (h 2).
In various embodiments, the opening height (h 2) can be correlated to the cavity height (h 10), the ratio (h 2/h 10) of the opening height (h 2) to the cavity height (h 10) being comprised between 10% and 60% (0.1 ≦ h2/h10 ≦ 0.6), preferably between 40 and 60%.
In various embodiments, the tortuosity of the bypass passage can be very simply characterized by defining a straight line extending through the bypass passage between the floor of the inlet portion and the outlet portion, which straight line is either absent (because the straight line cannot reach the floor or pass through the bypass passage without abutting the refractory element), or forms an angle (θ) with the vertical axis (Z) which is not more than 70 °, preferably not more than 60 °, more preferably not more than 45 °.
In various embodiments, the filter ledge (1L) "is higher" than the wall ledge (2L). In other words, the filter ledge distance (d 1L) can be greater than the wall ledge distance (d 2L) (i.e., d1L > d 2L). Alternatively, the filter ledge (1L) may be "lower" than the wall ledge (2L). In other words, the filter ledge distance (d 1L) can be lower than the wall ledge distance (d 2L) (i.e., d1L < d 2L). But the filter rung is not flush with the wall rung, i.e., the filter rung distance (d 1L) is not equal to the wall rung distance (d 2L) (i.e., d1L ≠ d 2L).
In various embodiments, the wall module (2) can comprise more than one wall crosspiece (2L) which are parallel to one another, never touch one another and are distributed over the height of the wall module (2). Similarly, the filter module (1) may comprise more than one filter crosspiece (1L) which are parallel to each other, never contact each other, and are distributed over the height of the filter module (1). The one or more wall ledges and/or filter ledges in combination define additional baffles in the bypass passage.
In various embodiments, each baffle is defined by at least a wall ledge and a filter ledge, wherein the bypass passage imparts a reversal to a flow direction component along the longitudinal axis (X) of the metal melt flowing from the inlet portion to the outlet portion of the cavity.
In at least one embodiment, the lower boundary of the filtering unit can be spaced from the floor of the cavity by a small distance (hd) comprised between 0 and 10cm (i.e., 0 ≦ hd ≦ 10 cm), and preferably between 2 and 5 cm. The upper boundary of the filter unit may be at a distance (hf + hd) from the bottom plate such that the ratio of said distance ((hf + hd)) to the opening height (h 2) ((hf + hd)/h 2) is comprised between 0.7 and 1.2 (i.e. 70% ≦ hf + hd)/h 2 ≦ 120%), preferably between 80% and 100%.
In at least one embodiment, a wall ledge (2L) projects from a portion of the width of the wall; in some embodiments, the wall ledge (2L) protrudes from the entire width of the wall.
In at least one embodiment, the filter rail (1L) protrudes from a portion of the width of the inlet side of the filter module (1); in some embodiments, the filter crosspiece (1L) protrudes from the entire width of the inlet side of the filter module (1).
Drawings
The following detailed description of the various disclosed methods, processes, compositions, and articles refers to the accompanying drawings in which:
fig. 1 shows a side cutaway view of a metallurgical facility including a tundish according to at least one embodiment of the presently disclosed subject matter.
FIG. 2 shows a top perspective view of the cavity of a tundish according to the present invention.
Fig. 3 (a) to 3 (d) show a number of different embodiments of the wall portion according to the invention.
Fig. 4 (a) to 4 (f) show side cut-away views of various embodiments of the filtration system according to the present invention.
Fig. 5 (a) and 5 (b) show side cut-away views illustrating a variety of different dimensions of a filtration system according to the present invention.
Fig. 6 (a) and 6 (b) show side perspective views illustrating how the cavity height (h 10) is measured.
Fig. 7 (a) and 7 (b) show top perspective views of two alternative embodiments of a tundish comprising more than one tundish outlet.
Detailed Description
In the continuous forming of metals, the metal melt is transferred from one metallurgical vessel to another, to a mold or tool. For example, as shown in fig. 1, a ladle (5L) is filled with a metal melt from a furnace (not shown) and is driven over a tundish (10) to discharge molten metal from the ladle into the tundish generally through a ladle shroud (5 s). The metal melt can then be cast from the tundish outlet (11 o) through a casting nozzle (15) into a mould or tool (25) to continuously form slabs, billets, beams, thin slabs and the like. Under the action of gravity, the metal melt flows out of the ladle into the tundish and then out of the tundish into the mould or tool. The flow rate may be controlled by a sliding gate valve mechanism in fluid communication with the outlets of the ladle and tundish. A ladle slide gate mechanism (5 g) can be used to control the flow out of the ladle and even to interrupt the flow in the sealing position. Similarly, a tundish sliding gate valve mechanism (not shown) may be used to control the flow out of the tundish and interrupt the flow in the sealing position. Typically, the flow out of the tundish is controlled by a plug (7) rather than a sliding gate valve mechanism.
Since the casting of the metal into the mould or tool is to be carried out continuously, the tundish acts as a buffer and the level (h 20) of molten metal in the tundish must remain substantially constant throughout the casting operation. However, the level (h 20) of the molten metal in the tundish drops during the replacement of an old ladle that has been emptied with a new ladle filled with molten metal. The flow out of the tundish is maintained substantially constant by (1) reducing the time for ladle replacement and (2) controlling the aperture of the tundish outlet (11 o) by means of a plug (7) or a sliding gate valve mechanism.
The presence of defects, such as inclusions and impurities, in cast metal parts is a concern. One source of such defects is the presence of foreign matter in the metal melt (20 m) present in the tundish. Slag (20 s) may also cause these defects. These defects are mainly due to debris and impurities present in the ladle or to wear of the refractory material in the pouring area of the tundish due to impact and friction between the metal melt and the refractory material. It is important to prevent such debris and impurities from reaching the tundish outlet to reduce the number of defects in the cast metal parts.
In accordance with various embodiments of the presently disclosed subject matter, as illustrated in fig. 1, a tundish (10) for continuous metal casting in accordance with at least one embodiment of the present invention defines a cavity having a cavity height (h 10) measured along a vertical axis (Z), a cavity length measured along a longitudinal axis (X), and a cavity width measured along a lateral axis (Y), wherein X × Y × Z. The cavity comprises an inlet portion (10 i) configured to receive a flow of metal melt (20 m) discharged by gravity from outside the tundish into the cavity of the tundish. The cavity comprises an outlet portion (10 o) comprising a tundish outlet (11 o) configured to discharge the metal melt from the cavity into a mould or tool (25). The cavity comprises a filter system separating the inlet portion (10 i) from the outlet portion (10 o) over the entire width of the tundish, and the filter system comprises a filter module (1) extending over the entire cavity width and extending from a floor (10 f) of the cavity along a vertical axis (Z) over a minimum filter module height (h 1) to a top surface, the filter module comprising an inlet side facing the inlet portion (10 i) of the tundish. The filter module (1) comprises: a filter unit (1 f) extending along the vertical axis (Z) over a filter height (hf) and provided with channels (1 c) extending from a channel inlet (i.e. an opening at the inlet side) to a channel outlet (i.e. an opening at the outlet side of the filter module (1) facing the outlet portion and being separated from the inlet side by a filter depth (tf)). The filtration system comprises a wall module (2) comprising a wall extending over the entire cavity width and along a vertical axis (Z) and defining one or more openings (2 o) distributed over the width of the wall and an opening height (h 2) measured from the floor (10 f) along the vertical axis (Z).
The filter module (1) is arranged closer to the outlet (11 o) than the wall module (2) and a bypass passage (2 b) having a maximum width (t 12) measured along the longitudinal axis (X) is defined between the wall module (2) and the filter module (1) such that the metal melt can only flow from the inlet portion through the one or more openings (2 o) to the inlet side of the filter module (1) and from the one or more openings (2 o) to the outlet portion by flowing through the channel of the filter unit (1 f) or the bypass passage (2 b),
a cavity: the cavity has a cavity height (h 10) measured along a vertical axis (Z), a cavity length measured along a longitudinal axis (X), and a cavity width measured along a transverse axis (Y), wherein X ±. Y ±. Z. The cavity is defined by a floor (10 f), surrounded by a peripheral wall. As illustrated in fig. 6 (a) and 6 (b), the cavity height (h 10) corresponds to the level of liquid filling the cavity measured from the floor (10 f) of the cavity, fluid above the liquid level flowing over the edge of the cavity out of the cavity (without the lid closing the cavity). In other words, the cavity height is the minimum height of the peripheral wall measured from the base plate to the top of the peripheral wall. If the tundish is provided with an overflow (10 s), the cavity height (h 10) is the separation of the floor (10 f) from the bottom of the overflow (see fig. 6 (b)).
The metal melt from the ladle (5L) is gravity poured into the receiving portion of the tundish cavity, thereby feeding the tundish with the metal melt. In order to protect the casting flow from atmospheric pollution, the ladle is usually provided with a ladle shroud (5 s). In order to prevent the pouring stream from perforating the floor of the cavity when it strikes, an impact pad (9) (or impact box) is usually provided in the impact area where the pouring stream strikes the floor. One tundish is usually supplied at a time from a single ladle (5L). The present disclosure may be applicable to multi-ladle feed systems.
As illustrated in fig. 7 (a) and 7 (b), the cavity may include more than one tundish outlet (11 o) supplied by the ladle (5L). In any case, there is always at least one metal feed area associated with one or more tundish outlets (11 o), each metal feed area defining a metal flow path extending between a receiving portion (shown in the figures as the location of the box or impact pad (9)) and the tundish outlet (11 o). According to the invention, it is sufficient that all flow paths have to be intercepted by at least one filtration system, as defined in more detail below. In the case of more than one tundish outlet (11 o), more than one filtration system may be required to meet this requirement.
As shown in fig. 1, 4 (a) to 4 (f), and 5 (a) and 5 (b), in the steady mode, i.e. when the ladle is currently discharging fresh metal melt into the tundish, the cavity is filled with a substantially constant level (h 20) of metal melt (20 m). Only during the period of time when the empty ladle (5L) is replaced with a new ladle, the tundish is not fed with fresh metal melt, and the metal melt level (h 20) in the tundish drops with time, since casting is continuing. The constant flow out of the tundish outlet is controlled by a plug (7) or sliding gate valve mechanism (not shown) at the tundish outlet (11 o) in response to the pressure reduction.
The level (h 20) of the metal melt (20 m) must not exceed the cavity height (h 10) (i.e. h20< h 10) in order to avoid the metal melt flowing over the edge or over the overflow (10 s) and out of the tundish. The level (h 20) of the metal melt in the steady mode may be comprised between 75% and 90% of the cavity height (h 10). Higher levels can unduly increase the risk of overflow, while lower levels can increase the cost of an oversized tundish.
And (3) a filtering system: the filter system divides the cavity into an inlet portion (10 i) and an outlet portion (10 o). The inlet portion (10 i) includes a region for fresh metal to be poured from the ladle (5L) into the tundish cavity. The outlet portion (10 o) includes a tundish outlet (11 o). The metal melt is poured into the inlet section and must flow through the filter system to flow out of the tundish outlet (11 o) into the mould or tool (25). The filtration system comprises a wall module (2) and a filter module (1) comprising a filtration unit (1 f) provided with channels (1 c) extending from a channel inlet, i.e. an opening at an inlet side of the filter module (1) facing the inlet portion (10 i), to a channel outlet, i.e. an opening at an outlet side facing the outlet portion (10 o).
The metal melt (20 m) has only two options, namely flow through the filter unit (1 f) through the channel (1 c) thereof or through a bypass passage (2 b) defined between the filter module (1) and the wall module (2).
Various embodiments of the presently disclosed subject matter relate to designing the filtration system such that in a stable mode more than 50% of the metal melt flowing through the filtration system flows through the channels of the filtration unit (1 f). As with any filtration system, the filtration unit (1 f) used in the tundish (10) can become clogged with debris and solids trapped upstream of the filtration unit. One way of measuring the degree of clogging of a filter unit is to monitor the evolution over time of the pressure drop (ap = (Pu-Pd)) upstream (Pu) of the filter unit with respect to downstream (Pd). As the degree of clogging increases, the pressure drop increases relative to the nominal pressure drop (Δ P0). In the present invention, it is preferred that more than 50%, preferably more than 60%, more preferably more than 75% of the metal melt flows through the filter unit (1 f) for a pressure drop up to two times the nominal pressure drop (i.e. for Δ P/Δ P0 ≦ 2). Conversely, it is preferred that less than 50%, preferably less than 40%, more preferably less than 25% of the flow passes through the bypass passage (2 b).
The filtration system of the present disclosure allows for the entrapment of large amounts of debris or other solids present in the metal melt prior to discharge of the metal melt into a mold or tool (25). At the same time, in case the filter unit (1 f) is excessively blocked, resulting in a high pressure drop across the filter unit, the metal melt may flow through the bypass passage (2 b) into the outlet portion (10 o). In this way, the metal melt does not become jammed in the inlet portion (10 i), which would result in the level of the metal melt rising to dangerously close to or above the cavity height (h 10) in the inlet portion, and with dire consequences of the metal melt overflowing from the tundish.
In contrast to the system described in KR 101853768 discussed above, the filtration system of the present disclosure does not require a weir between the filter module (1) and the tundish outlet (11 o) downstream of the filter module (1). The design of the filtration system of the present disclosure is continued.
Wall module (2): the wall module (2) is one of the two basic components of the filtration system of the invention, which divides the cavity into an inlet portion (10 i) and an outlet portion (10 o). The wall module (2) is adjacent to the inlet portion (10 i) and is separated from the tundish outlet by the filter module (1). The wall module (2) comprises a wall which extends over the entire cavity width and extends along a vertical axis (Z) up to an upper edge. The wall defines one or more openings (2 o) distributed over the width of the wall and an opening height (h 2) measured from the floor (10 f) along a vertical axis (Z). The upper edge of the wall is above the steady level (h 20) of the metal melt. The upper edge is generally positioned at a distance from the floor (10 f) comprised between 90% and 100% of the cavity height (h 10), preferably between 95% and 100% of h 10. In case the tundish is provided with an overflow (10 s), the upper edge may extend above h10, preferably flush with the free edge of the tundish not comprising the overflow. This is especially the case if the overflow (10 s) is located in the outlet portion (10 o).
As illustrated in fig. 3 (a) -3 (d), the one or more openings (2 o) may have various geometries. In the embodiment illustrated in fig. 3 (a) to 3 (b), the single opening (2 o) extends from the floor (10 f) to the lower edge of the wall, which may be straight and parallel to the floor (see fig. 3 (a)), or curved (see fig. 3 (b)). The opening height (h 2) is the distance from the floor to the farthest point of the lower edge. In a variant of this embodiment, the opening extends from the lower boundary (forming a step) at a distance from the floor (10 f) of up to 5% of the cavity height (h 10) to the lower edge of the wall. The opening height (h 2) is defined as the separation distance of the floor from the farthest point of the lower edge (i.e., ignoring the presence of steps). The presence of the step over the entire width of the cavity hinders the evacuation of all the metal melt remaining in the tundish, so that the inlet portion (10 i) is filled to the height of the step. The step may be provided with a drain passage to avoid this problem. In an alternative embodiment illustrated in fig. 3 (c), the wall may comprise more than one opening (2 o). The top opening is defined as the opening having the boundary furthest away from the floor (10 f). The opening height (h 2) is defined as the separation distance of the boundary from the floor. Fig. 3 (c) shows the same circular opening. It is clear that the more than one opening may have any geometry and size as desired.
In order to flow from the inlet portion to the outlet portion, the metal melt has to pass through the one or more openings of the wall. There is no alternative unless the level of the metal melt in the inlet portion increases beyond the upper edge of the wall. The ratio (h 2/h 10) of the opening height (h 2) to the cavity height (h 10) is preferably comprised between 10% and 60% (i.e. 0.1. Ltoreq. H2/h 10. Ltoreq.0.6), preferably between 15% and 50%, more preferably between 20% and 40%. The opening height (h 2) is important because, as shown in fig. 1 (dashed line), it forces the metal melt to flow downwards after it has bounced upwards towards the surface of the metal melt by striking the impact pad (9). The presence of a step protruding from the floor may be used to trap the heaviest solids, but its presence is not essential.
The wall module (2) further comprises a wall ledge (2L) projecting from the entire width of the wall at a wall ledge distance (d 2L) from the bottom plate (10 f) and extending towards the inlet side of the filter module (1) without contacting it, the wall ledge (2L) having a width (t 2L) measured along the longitudinal axis (X). For walls comprising a single opening with a straight upper edge, the wall ledge may be flush with the upper edge such that the wall ledge distance (d 2L) is equal to the opening height (h 2) (i.e., h2L = h 2), for example as shown in fig. 1, fig. 3 (a), fig. 4 (b), fig. 4 (e), and fig. 5 (a). Alternatively, the wall ledge (2L) may be any distance (d 2L) from the floor such that h2< d2L <80% h10, preferably d2L is less than 70% of h 10. Embodiments in which the wall ledges are not flush with the upper edge of the top opening are illustrated in fig. 3 (d), fig. 4 (c), fig. 4 (d), fig. 4 (f) and fig. 5 (b). In some embodiments, a wall ledge (2L) protrudes from a portion of the width of the wall; in some embodiments, the wall ledge (2L) protrudes from the entire width of the wall.
The wall module (2) may comprise more than one wall crosspiece (2L) distributed over the height of the wall module (2), as illustrated in fig. 4 (e). In various embodiments, the more than one wall rung is straight and extends parallel to each other and to the floor (10 f). The more than one wall crosspiece (2L) preferably do not touch each other if they are not parallel to each other. The wall ledge distance (d 2L) is the distance from the wall ledge closest to the floor (10 f) to the floor. In various embodiments, the walls and wall ledges (2L) are made of refractory material, preferably the same refractory material lining the peripheral walls and floor of the cavity.
A filter module: the filter module (1) extends over the entire cavity width and extends from the floor (10 f) of the cavity along a vertical axis (Z) over a minimum filter module height (h 1) to the top surface. The filter module is positioned adjacent to the outlet portion (10 o) and comprises an inlet side facing the inlet portion (10 i) of the tundish. The filter module (1) comprises a filter unit (1 f) provided with channels (1 c) extending from a channel inlet (i.e. an opening at the inlet side) to a channel outlet (i.e. an opening at the outlet side of the filter module (1) facing the outlet portion and being separated from the inlet side by a filter depth (tf)). The filter unit (1 f) preferably extends vertically below the top surface, such that the top surface is not part of the filter unit (1 f). The filter unit (1 f) may extend over any part of the tundish width as desired. The larger the area in the plane (Y, Z), the higher the volume throughput through a filtration unit of a given permeability.
In at least one embodiment, the filter ledge (1L) protrudes from the entire width of the inlet side of the filter module (1) at a filter ledge distance (d 1L) from the bottom plate (10 f) that exceeds the opening height (h 2) (i.e., d1L > h 2). The filter ledges (1L) are offset (i.e. d1L ≠ d 2L) with respect to the wall ledges (2L) so that they do not face each other at the same height. The filter rail (1L) extends towards the wall modules (2) without contacting the wall modules or the wall rail, the filter rail (1L) having a width (t 1L) measured along the longitudinal axis (X). In some embodiments, the filter rail (1L) protrudes from a portion of the width of the inlet side of the filter module (1); in some embodiments, the filter crosspiece (1L) protrudes from the entire width of the inlet side of the filter module (1).
The filter module (1) may comprise more than one filter crosspiece (1L) distributed over the height of the filter module (1), as illustrated in fig. 4 (f). In at least one embodiment, the more than one filter rung are straight and extend parallel to each other and to the floor (10 f). The more than one filter rung (1L) preferably do not contact each other and do not contact the wall rung (2L) if they are not parallel to each other. The filter ledge distance (d 1L) is the distance from the filter ledge closest to the floor (10 f) to the floor.
In one embodiment, the filter ledge to floor distance (d 1L) is greater than the wall ledge distance (d 2L) (i.e., d1L > d 2L). This embodiment is shown in fig. 1, 4 (a) to 4 (c), 4 (e), 5 (a) and 5 (b). In an alternative embodiment shown in fig. 4 (d) and 4 (f), the filter ledge to floor distance (d 1L) is less than the wall ledge distance (d 2L) (i.e., d1L < d 2L).
The filtration unit (1 f) may be any type of filtration unit known in the art of continuous metal casting. The function of the filtration unit (1 f) is to retain all debris and solids (= retentate) upstream of the filtration unit, while allowing the metal melt to flow through the filtration unit (= filtrate) through the channel (1 c) and thence to the tundish outlet (11 o). These channels may be straight or tortuous, the dimensions (cross-section and length) of which help to define the permeability of the filtration unit when tortuous. The permeability of the filter unit depends on the requirements of the specific application and the skilled person knows how to optimize the characteristics of the filter unit (1 f) accordingly.
The lower boundary of the filtering unit (1 f) can be at a small distance (hd) from the floor (10 f) of the cavity, this distance being comprised between 0 and 10cm (i.e. 0 hd 10 cm), and preferably between 2 and 5 cm. Similarly, the upper boundary of the filter unit (1 f) may be spaced from the bottom plate (10 f) by a distance (hf + hd) such that the ratio of said distance ((hf + hd)) to the opening height (h 2) ((hf + hd)/h 2) is comprised between 0.7 and 1.2 (i.e. 70% ≦ hf + hd)/h 2 ≦ 120%), preferably between 80% and 100%.
A bypass passage: the bypass passage (2 b) defined in the filtration system is the gist of the present invention. This bypass passage must ensure that casting continues smoothly even in the event of the filtration unit (1 f) being blocked, and at the same time it does not provide an easier flow path than through the filtration unit (1 f), so that in steady conditions at least 50% of the metal flows through the filtration unit to the outlet portion (10 o) of the tundish. To this end, the bypass passage of the present disclosure is designed to impart a first and a second reversal of the direction of the velocity vector along the longitudinal direction (X) to the metal melt stream. This is achieved by the combination of a wall ledge (2L) and a filter ledge (1L) which provide a barrier to the passage defined between the wall and the filter module (1).
As discussed with respect to fig. 1, 4 (a) -4 (c), 4 (e), 5 (a), and 5 (b), the wall ledge (2L) may be lower than the filter ledge (1L) (i.e., closer to the floor (10 f)). In this way, the part of the metal melt above the opening height (h 2) from the bottom plate (10 f) is blocked by the wall and redirected downwards (i.e. towards the opening (2 o)), thereby being redirected towards the filter module (1) upon approaching the bottom plate (10 f). The metal melt may flow up right behind the wall until it reaches the lower surface of the wall ledge (2L). If the wall ledge (2L) is flush with the opening (i.e. d2L = h 2), the metal melt cannot flow up right behind the wall at all. Similarly, the part of the metal melt below the opening height (h 2) from the bottom plate (10 f) cannot flow up right behind the wall and is forced towards the filter module (1). When the metal melt hits the lower surface of the wall ledge (2L), the flow is redirected towards the filter module (1). The filter portion flows straight (parallel to the longitudinal axis (X)) or downwards against the filter unit (1 f). The bypass portion flows upwards against the inlet side of the filter module (1) until it hits the lower surface of the filter crosspiece (1L). This redirects the flow in the opposite direction of the velocity vector component (= X component) parallel to the longitudinal axis (X) so that the X component of the flow returns in the direction of the inlet section (10 i). The flow hits the wall and the X-component of the velocity vector reverses again so that the flow returns in the direction of the outlet portion (10 o). As shown in fig. 4 (e), the wall module (2) may comprise a second wall ledge above the wall ledge (2L) to force the velocity vector towards a direction more parallel to the longitudinal axis (X). The filter unit may comprise additional filter ledges to be combined with corresponding additional wall ledges as additional baffles to alter the X-component of the velocity vector.
As discussed with respect to fig. 4 (d) and 4 (f), the filter ledge (1L) may alternatively be lower than the wall ledge (2L) (i.e., closer to the floor (10 f)). In this way, when a resistance to flow through the filter unit (1 f) is felt, a portion of the metal melt is redirected upwards and hits the lower surface of the filter crosspiece (1L). This redirects the flow in the opposite direction of the X component of the velocity vector so that the X component of the flow returns in the direction of the inlet section (10 i). The flow then hits the wall and is redirected upwards again until it hits the lower surface of the wall ledge (2L), forcing it to redirect the X-component of the velocity vector again in the direction of the outlet portion (10 o). Thus, the metal melt may continue to flow across the filter module (1) towards the outlet portion (10 o) and down to the tundish outlet (11 o). The filter unit may comprise additional filter ledges to be combined with corresponding additional wall ledges as additional baffles to alter the X-component of the velocity vector.
The technician can adjust the desired portion of metal melt forced through a given filter unit (1 f) by varying the size of the bypass passage (2 b) to make it more or less tortuous and thus more or less easy to circulate than through the filter unit. Relevant dimensions are, for example, maximum width (t 12) (where t12> 0), filter rail width (t 1L), wall rail width (t 2L), filter rail distance (d 1L), wall rail distance (d 2L), wall rail-to-filter rail separation distance measured along vertical axis (Z) (| d1L-d2L |), and the like.
According to at least one embodiment, the ratio ((t 1L + t 2L)/t 12) of the sum of the widths (t 1L, t 2L) of the filter and wall crosspieces (1L, 2L) to the maximum width (t 12) of the bypass passage (2 b) is comprised between 20% and 150% (i.e. 0.2 ≦ (t 1L + t 2L)/t 12 ≦ 1.5), preferably between 30% and 120%, more preferably between 50% and 100%.
The portion flowing through the filter unit also depends on the opening height (h 2) and the minimum filter module height (h 1). According to at least one embodiment, the ratio (h 2/h 1) of the opening height (h 2) to the filter module height (h 1) is comprised between 20% and 95% (i.e. 0.2 ≦ h2/h1 ≦ 0.95), preferably between 40% and 80%.
A simple way to characterize the tortuosity of the bypass passage is to plot a straight line extending from the floor (10 f) in the inlet portion through the bypass passage (2 b) to the outlet portion. According to at least one embodiment, such a straight line is not present, because the line cannot reach the floor, as illustrated in fig. 4 (b) and 4 (d), or the line forms an angle (θ) with the vertical axis (Z), which is not more than 70 °, preferably not more than 60 °, more preferably not more than 45 °, most preferably not more than 35 °. This angle is illustrated in fig. 4 (a) and 4 (c).
The above conditions prevent the metal melt from finding a straight flow path from the bottom plate (where the metal melt bounces after being discharged from the ladle (5L)) through the bypass passage (2 b). If such a flow path is available, a significant portion of the molten metal will bypass the filter unit (1 f) and instead flow through the bypass passage, which is clearly unsatisfactory.
For example, for a tundish in which the cavity height (h 10) is comprised between 800 and 1800mm, preferably between 1000 and 1300mm, the opening height (h 2) may be comprised between 80 and 600mm, preferably between 100 and 500 mm. The maximum width (t 12) of the bypass passage (2 b) separating the wall from the filter module may be comprised between 60 and 800mm, preferably between 80 and 600 mm. The distance (d 1L) of the filter crosspieces from the bottom plate can be comprised between 80 and 650mm, preferably between 100 and 620mm, and the distance (d 2L) of the wall crosspieces from the bottom plate can be comprised between 80 and 600 mm.
In various embodiments, the wall ledge width (t 2L) and the filter ledge width (t 1L) can be comprised between 20 and 200 mm; in some embodiments, the wall ledge width (t 2L) and the filter ledge width (t 1L) may be comprised between 50 and 150 mm. In at least one embodiment, each of the wall rail width (t 2L) and the filter rail width (t 1L) has a minimum value of 20 mm. In at least one embodiment, each of the wall rail width (t 2L) and the filter rail width (t 1L) has a maximum value of 200 mm. However, in some embodiments, the wall ledge width (t 2L) and the filter ledge width (t 1L) may be adjusted or customized based on the size and dimensions of the tundish (10). However, in various embodiments, each of the wall rail width (t 2L) and the filter rail width (t 1L) is a non-zero value; in other words, various embodiments of the presently disclosed subject matter include the presence of wall ledges and filter ledges regardless of their respective widths.
An advantage of the tundish of the present disclosure is that most of the scrap and other solids are removed from the metal melt (20 m) prior to casting the metal melt into the tool (25). When the filter unit (1 f) is new or its passage is clean and free of any solid debris, the filter unit is characterized by: the pressure drop (Δ P) between the inlet side and the outlet side of the filter unit is equal to the nominal pressure drop (Δ P0). In use, debris and other solids trapped by the channels accumulate and partially and eventually completely block some or all of the channels. The pressure drop (Δ P) increases, making it more difficult for the metal melt to flow through the filter unit (1 f). As the pressure drop (Δ P) increases, it is found that the metal melt flows more easily through the bypass passage (2 b) than through the filter unit.
For example, when the filter unit (1 f) is fully operational (e.g., Δ P/Δ P0< 2), more than 50%, preferably more than 60%, more preferably more than 75%, most preferably more than 85% of the metal melt flows through the filter unit (1 f), the metal melt flowing through the filter system from the inlet portion (10 i) to the outlet portion (10 o) flows through the filter unit (1 f), and the remainder flows through the bypass passage (2 b). However, in case the filter unit is significantly blocked (i.e. the pressure drop reaches high values, for example Δ P/Δ P0> 10), it was found that the metal melt hardly flows through the filter unit (1 f) and more easily flows out by flowing through the bypass passage (2 b). This reduces the risk of seeing the metal melt level (h 20) rising in the inlet portion to a dangerous level close to the cavity height (h 10).
In addition to being efficient and easy to modularize to meet the requirements of a particular application, the implementation of this solution is also very simple, requiring only two modules of simple design, respectively the wall module (2) and the filter module (1). This solution is therefore also very economical and ensures continuity during metal casting.
A tundish (10) for continuous metal casting, the tundish defining a cavity, wherein the cavity has a cavity height (h 10) measured along a vertical axis (Z), a cavity length measured along a longitudinal axis (X), and a cavity width measured along a transverse axis (Y), wherein X ±. Y ±. Z, and wherein the cavity comprises: an inlet portion (10 i) configured to receive a flow of metal melt (20 m) discharged by gravity from outside the tundish into the cavity of the tundish; an outlet portion (10 o) comprising an outlet (11 o) configured to expel the metal melt from the cavity into a mould; and a filter system separating the inlet portion (10 i) from the outlet portion (10 o) over the entire cavity width. The filtration system comprises a filter module (1) extending over the entire cavity width and extending inside said cavity, wherein the filter module comprises an inlet side facing an inlet portion (10 i) of the tundish and extending from a bottom plate (10 f) of the cavity to a top surface, the shortest distance of the top surface measured along the vertical axis (Z) from the bottom plate being equal to a minimum filter module height (h 1), and wherein the filter module (1) comprises a filter unit (1 f) extending along the vertical axis (Z) over a filter height (hf) and provided with channels (1 c) extending from channel inlets, i.e. openings at the inlet side facing the inlet portion (10 i) of the tundish, to channel outlets, i.e. openings at the outlet side of the filter module (1) facing the outlet portion and being spaced from the inlet side by a filter depth (tf). The filter system further comprises a wall module (2) comprising a wall extending over the entire cavity width and inside said cavity and defining one or more openings (2 o) distributed over the width of the wall and an opening height (h 2) measured from the floor (10 f) along the vertical axis (Z). The filter module (1) being arranged closer to the outlet (11 o) than the wall module (2) and defining a bypass passage (2 b) between the wall module (2) and the filter module (1) having a maximum width (t 12) measured along the longitudinal axis (X) such that the metal melt can only flow from the inlet portion to the inlet side of the filter module (1) through the one or more openings and from the one or more openings to the outlet portion through the channel flowing through the filter unit (1 f) or the bypass passage (2 b), characterized in that,
a. the ratio (h 2/h 1) of the opening height (h 2) to the filter module height (h 1) is comprised between 20% and 95% (0.2 ≦ h2/h1 ≦ 0.95), preferably between 40% and 80%,
b. a wall crosspiece (2L) projecting from the entire width of the wall at a wall crosspiece distance (d 2L) (i.e. d2L ≦ h 1) from the bottom plate (10 f) of not more than the minimum filter module height (h 1) and extending towards the inlet side of the filter module (1) without contacting the filter module, the wall crosspiece (2L) having a width (t 2L) measured along the longitudinal axis (X), wherein 0 t2L comprises t2L and t12,
c. the filter crosspiece (1L) protrudes from the entire width of the inlet side of the filter module (1) at a filter crosspiece distance (d 1L) from the bottom plate (10 f) that exceeds the opening height (h 2) (i.e. d1L > h 2) and is offset with respect to the wall crosspiece (2L) (i.e. d1L ≠ d 2L); and which extends towards the wall modules (2) without contacting the wall modules or the wall crosspieces, the filter crosspiece (1L) having a width (t 1L) measured along the longitudinal axis (X), wherein 0 t1L and t12 are
d. The ratio ((t 1L + t 2L)/t 12) of the sum of the widths (t 1L, t 2L) of the filter and wall ledges (1L, 2L) to the maximum width (t 12) of the bypass passage (2 b) is comprised between 20% and 150% (i.e. 0.2 ≦ (t 1L + t 2L)/t 12 ≦ 1.5), preferably between 30% and 120%, more preferably between 50% and 100%.
The foregoing description is given for clearness of understanding only, and no unnecessary limitations should be understood therefrom, as modifications within the scope of the invention may be apparent to those having ordinary skill in the art.
Claims (14)
1. A tundish (10) for continuous metal casting, the tundish defining a cavity, wherein the cavity has a cavity height (h 10) measured along a vertical axis (Z), a cavity length measured along a longitudinal axis (X), and a cavity width measured along a transverse axis (Y), wherein X × Y × Z, and wherein the cavity comprises:
an inlet portion (10 i) configured for receiving a flow of metal melt (20 m) discharged by gravity from outside the tundish into the cavity of the tundish;
an outlet portion (10 o) comprising an outlet (11 o) configured for discharging the metal melt from the cavity into a mould;
a filter system separating the inlet portion (10 i) from the outlet portion (10 o) over the entire cavity width, the filter system comprising
A filter module (1) extending over the entire cavity width and inside the cavity, wherein the filter module comprises an inlet side facing the inlet portion (10 i) of the tundish and extending from a bottom plate (10 f) of the cavity to a top surface, the shortest distance of which measured along the vertical axis (Z) from the bottom plate being equal to a minimum filter module height (h 1), and wherein the filter module (1) comprises a filter unit (1 f) extending along the vertical axis (Z) over a filter height (hf) and being provided with channels (1 c) which are provided with channels (1 c)
From the channel inlet, i.e. the opening at the inlet side of the inlet portion (10 i) facing the tundish
An opening at an outlet side of the filter module (1) facing the outlet portion and separated from the inlet side by a filter depth (tf); and
a wall module (2) comprising a wall extending over the entire cavity width and inside the cavity and defining one or more openings (2 o) distributed over the width of the wall and an opening height (h 2) measured from the floor (10 f) along the vertical axis (Z),
wherein the filter module (1) is arranged closer to the outlet (11 o) than the wall module (2) and a bypass passage (2 b) having a maximum width (t 12) measured along the longitudinal axis (X) is defined between the wall module (2) and the filter module (1) such that the metal melt can only flow from the inlet portion through the one or more openings to the inlet side of the filter module (1) and from the one or more openings to the outlet portion by flowing through the channel or the bypass passage (2 b) of the filter unit (1 f),
it is characterized in that the preparation method is characterized in that,
a wall rail (2L) projecting from the wall of the wall module (2) at a wall rail distance (d 2L) (i.e. d2L ≦ h 1) from the base plate (10 f) of the minimum filter module height (h 1) and extending towards the inlet side of the filter module (1) without contacting the filter module (1), the wall rail (2L) having a width (t 2L) measured along the longitudinal axis (X), wherein 20mm ≦ t2L ≦ t12,
a filter crosspiece (1L) protrudes from the inlet side of the filter module (1) at a filter crosspiece distance (d 1L) (i.e. d1L > h 2) from the bottom plate (10 f) exceeding the opening height (h 2) and is offset (i.e. d1L ≠ d 2L) with respect to the wall crosspiece (2L), the filter crosspiece extending towards the wall module (2) without contacting the wall module or the wall crosspiece, the filter crosspiece (1L) having a width (t 1L) measured along the longitudinal axis (X), wherein 20mm t1L consists of t12.
2. Tundish according to claim 1, wherein the ratio (h 2/h 1) of the opening height (h 2) to the filter module height (h 1) is comprised between 20% and 95% (0.2 ≦ h2/h1 ≦ 0.95), or between 40% and 80%.
3. A tundish according to claim 1, wherein the ratio ((t 1L + t 2L)/t 12) of the sum of the widths (t 1L, t 2L) of the filter ledge (1L) and the wall ledge (2L) to the maximum width (t 12) of the bypass passage (2 b) is comprised between 20% and 150% (i.e. 0.2 ≦ (t 1L + t 2L)/t 12 ≦ 1.5), or between 30% and 120%, or between 50% and 100%.
4. A tundish according to claim 1, wherein the wall module (2) comprises a single opening (2 o) extending from a lower boundary spaced from the floor (10 f) by a distance of from 0% to 5% of the cavity height (h 10) to a lower edge of the wall, thereby defining the opening height (h 2) as the distance the floor is spaced from the furthest point of the lower edge.
5. A tundish according to claim 1, wherein the wall module (2) comprises more than one opening (2 o), wherein a top opening is defined as the opening having the boundary furthest from the floor (2 f), the boundary furthest from the floor (2 f) being spaced from the floor by the opening height (h 2).
6. Tundish according to claim 1, wherein the ratio (h 2/h 10) of the opening height (h 2) to the cavity height (h 10) is comprised between 10% and 60% (0.1 ≦ h2/h10 ≦ 0.6), or between 40 and 60%.
7. A tundish according to claim 1, wherein a straight line extending between the floor (10 f) of the inlet portion and the outlet portion through the bypass passage (2 b)
Is absent, or
Forms an angle (θ) with the vertical axis (Z) of no more than 70 °, or no more than 60 °, or no more than 45 °.
8. The tundish of claim 1, wherein the filter ledge distance (d 1L) is greater than the wall ledge distance (d 2L) (i.e., d1L > d 2L).
9. A tundish according to claim 1, wherein the wall module (2) comprises more than one wall ledge (2L) which are parallel to each other, never contact each other, and are distributed over the height of the wall module (2).
10. A tundish according to claim 1, wherein the filter module (1) comprises more than one filter ledge (1L) which are parallel to each other, never contact each other, and are distributed over the height of the filter module (1).
11. Tundish according to claim 1, wherein the bypass passage (2 b) imposes a reversal of the component of the flow direction along the longitudinal axis (X) of the metal melt flowing from the inlet portion (10 i) to the outlet portion (10 o) of the cavity.
12. The tundish of claim 1,
the lower boundary of the filtering unit (1 f) is at a small distance (hd) from the floor (10 f) of the cavity, said small distance being comprised between 0 and 10cm (i.e. 0 hd 10 cm), or between 2 and 5cm, and/or wherein,
the upper boundary of the filter unit (1 f) is at a distance (hf + hd) from the base plate (10 f) such that the ratio of the distance ((hf + hd)) to the opening height (h 2) ((hf + hd)/h 2) is comprised between 0.7 and 1.2 (i.e. 70% ≦ hf + hd)/h 2 ≦ 120%), or between 80% and 100%.
13. A tundish according to claim 1, wherein the wall crosspiece (2L) projects from a portion of the width of the wall or the entire width of the wall.
14. Tundish according to claim 1, wherein the filter crosspiece (1L) protrudes from a portion of the width of the inlet side of the filter module (1) or the entire width of the inlet side of the filter module (1).
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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EP21172786.2 | 2021-05-07 | ||
EP21172786 | 2021-05-07 |
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CN115301935A true CN115301935A (en) | 2022-11-08 |
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CN202210473096.8A Pending CN115301935A (en) | 2021-05-07 | 2022-04-29 | Tundish with filter module |
CN202221103552.1U Active CN218693828U (en) | 2021-05-07 | 2022-04-29 | Tundish for continuous metal casting |
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CN202221103552.1U Active CN218693828U (en) | 2021-05-07 | 2022-04-29 | Tundish for continuous metal casting |
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US (1) | US20240253111A1 (en) |
EP (1) | EP4334051A1 (en) |
JP (1) | JP2024519531A (en) |
KR (1) | KR20240004469A (en) |
CN (2) | CN115301935A (en) |
AU (1) | AU2022268640A1 (en) |
BR (1) | BR112023023191A2 (en) |
CA (1) | CA3216140A1 (en) |
CL (1) | CL2023003269A1 (en) |
MX (1) | MX2023012604A (en) |
TW (1) | TW202308769A (en) |
WO (1) | WO2022234109A1 (en) |
Family Cites Families (7)
Publication number | Priority date | Publication date | Assignee | Title |
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JPS59189050A (en) * | 1983-04-09 | 1984-10-26 | Nippon Steel Corp | Removal of nonmetallic inclusion from molten metal |
JPS60221158A (en) * | 1984-04-16 | 1985-11-05 | Nisshin Steel Co Ltd | Continuous casting installation |
JPS62197251A (en) * | 1986-02-24 | 1987-08-31 | Nisshin Steel Co Ltd | Tundish for continuous casting |
US4995592A (en) * | 1988-12-22 | 1991-02-26 | Foseco International Limited | Purifying molten metal |
KR200303465Y1 (en) | 2002-12-13 | 2003-02-07 | 주식회사 포스코 | One body type tundish dam with horizontal dam filter |
KR101853768B1 (en) * | 2015-12-10 | 2018-05-02 | 주식회사 포스코 | Tundish and method for making a filter |
KR101834216B1 (en) | 2016-06-08 | 2018-03-05 | 주식회사 포스코 | Molten material processing apparatus and processing method |
-
2022
- 2022-04-29 CN CN202210473096.8A patent/CN115301935A/en active Pending
- 2022-04-29 CN CN202221103552.1U patent/CN218693828U/en active Active
- 2022-05-04 TW TW111116817A patent/TW202308769A/en unknown
- 2022-05-06 MX MX2023012604A patent/MX2023012604A/en unknown
- 2022-05-06 KR KR1020237038252A patent/KR20240004469A/en unknown
- 2022-05-06 EP EP22727924.7A patent/EP4334051A1/en active Pending
- 2022-05-06 AU AU2022268640A patent/AU2022268640A1/en active Pending
- 2022-05-06 WO PCT/EP2022/062319 patent/WO2022234109A1/en active Application Filing
- 2022-05-06 JP JP2023568349A patent/JP2024519531A/en active Pending
- 2022-05-06 CA CA3216140A patent/CA3216140A1/en active Pending
- 2022-05-06 BR BR112023023191A patent/BR112023023191A2/en unknown
- 2022-05-06 US US18/289,580 patent/US20240253111A1/en active Pending
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CL2023003269A1 (en) | 2024-05-24 |
US20240253111A1 (en) | 2024-08-01 |
JP2024519531A (en) | 2024-05-15 |
CN218693828U (en) | 2023-03-24 |
TW202308769A (en) | 2023-03-01 |
AU2022268640A1 (en) | 2023-11-09 |
MX2023012604A (en) | 2023-11-03 |
EP4334051A1 (en) | 2024-03-13 |
WO2022234109A1 (en) | 2022-11-10 |
KR20240004469A (en) | 2024-01-11 |
BR112023023191A2 (en) | 2024-01-30 |
CA3216140A1 (en) | 2022-11-10 |
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