EP1781435B1

EP1781435B1 - Ingot casting apparatus and method

Info

Publication number: EP1781435B1
Application number: EP05758896A
Authority: EP
Inventors: Vladimir Alguine; Paul William Cleary; John Grandfield; Vu Nguyen; Mahesh Prakash; Patrick Rohan; Mathew Sinnott
Original assignee: Cast Centre Pty Ltd
Current assignee: Cast Centre Pty Ltd
Priority date: 2004-07-14
Filing date: 2005-07-13
Publication date: 2010-06-16
Anticipated expiration: 2025-07-13
Also published as: DE602005021887D1; CN100423870C; EP1781435A1; CN1984735A; EP1781435A4; ATE471220T1; WO2006005131A1

Abstract

A casting wheel (110) for use in filling ingot moulds in an ingot casting line, including an annular member arranged to be mounted for rotation, and a plurality of spouts (116) arranged around the periphery of the annular member (114), each spout (116) having two side walls (130) and a base (128), each side wall (130) having an open edge (135) for contacting molten metal from a molten metal source, the initial section (137) of the side wall extending from the open edge (135) being shaped to be substantially parallel to the initial section of the side wall extending from the open edge of an adjacent spout.

Description

Field of the invention

This invention concerns the use of casting wheels to fill ingot moulds of an ingot casting line.

Background of the invention

The chain conveyor ingot casting process is widely used to cast non-ferrous metals including aluminium, zinc, magnesium and lead. The chain conveyor process has a series of open cast iron moulds for casting ingots which are, usually of trapezoidal cross section on a conveyor system. The conveyor may be straight or circular and is generally up to 20m long. The moulds are filled at one end of the conveyor and as they progress along the conveyor, the ingot cools (by way of air or water cooling) and at the end of the conveyor the solid ingot is ejected.
Casting wheels (or rotating launders) are commonly used in the non ferrous metals industries to transfer molten metal from a launder to the mould in equal quantities. The general construction of a casting wheel includes a number of spouts positioned on the perimeter of the wheel is designed to rotate about its axis. The casting wheel is usually arranged relative to the mould conveyor such that each spout on the casting wheel indexes with a corresponding mould to allow filling of the mould with the molten metal from the spout.
Document AU 717 796 B2 discloses a casting wheel according to the preamble of claim 1.
A problem associated with known casting wheels is that during the filling process the melt surface exposed to air oxidises. This oxide becomes partially entrained in the liquid or floats on the top surface of the ingot. Automatic skimming may be used to remove the top layer but this represents a loss of material and does not remove entrained material.
The amount of dross is a function of the area of metal in the filling system exposed to air which, in turn, depends on the nature of the flow.
This problem is compounded when consideration is given to running the casting machine at a higher production rate. This is often accomplished by increasing the length of the conveyor system, in order to increase the length available for exposing the ingot moulds to cooling water or air, and then running the conveyor at a higher linear speed.
This means that for higher production rates, each ingot must be filled in a shorter time. However, shorter filling times result in greater fluid velocities and kinetic energy in the fluid in the filling spout and in the ingot. This results in an increase in the spreading of fluid against the solid surfaces of the filling system and mould thereby increasing the surface area of fluid and the degree of oxidation and dross formation.
In order to provide for less dross formation during casting at normal and higher conveyor speeds, it is desirable to reduce the surface area of the fluid in the flowing molten metal and thus reduce the amount of oxide formation.

Summary of the invention

In order to solve the above mentioned problem, according to the invention, the casting wheel further has the features mentioned in the characterising portion of claim 1. The applicants have found that by having the plane of the initial section of the side wall extending from the open edge substantially parallel to the initial section of an adjacent spout, a smaller contact angle is presented to the incoming molten metal resulting in less spreading and fanning out of the molten metal entering the spout of the casting wheel. In a preferred form of this embodiment, the spouts are equally spaced around the annular member with the side walls of each spout abutting the side wall of an adjacent spout. In this way, the abutting side wall of adjacent spouts act as a flow divider to direct flow of molten metal entering the casting wheel to the respective spouts. After the initial section of the side wall, the side wall is concave shaped as it extends towards the base of the spout. The concave shape of the base or section of the side wall, allows the direction of flow of the molten metal to be changed without causing excess spreading. The absence of a defined joining wall between the side wall or edge and the base contributes to this lessening of fluid spreading.
To assist with this redirection of flow and to minimise spreading of the fluid, the side walls and the base wall may be provided with flow directors, preferably in the form of ribs, protrusions or grooves, extending towards the outlet of the spout.
The outlet end of the spout may further be provided with a cover so that the outlet from the spout forms a closed conduit. This enables the molten metal to flow into the ingot mould in a more controlled manner, thereby further reducing the energy of the fluid entering the mould and subsequent spreading of the fluid in the mould. The base of the spout may converge towards the cover of the spout.
In order to minimise the disturbance of the molten metal stream exiting from the launder into the wheel, the slope of the spout in the region of contact with the molten metal stream is given a specific parabolic shape. Hence in another form of this embodiment of the invention, the base section of the spout may be provided with a convex section which produces an undulation in the base to more smoothly direct the flow of the molten metal entering the spout towards the exit. This convex section is preferably in the initial contact area of the base with the incoming molten metal.
Additionally, by providing a spout with a construction in accordance with the invention, the adjoining wall between adjacent sprouts formed by abutting initial sections of the adjacent side walls, can be lower relative to the outlet of the spout. This enables the launder outlet to the spout to be lowered relative to the outlet of the spout and the ingots mould thereby reducing the head loss from the launder feeder to the bottom of the mould. This reduction in head loss reduces the possible kinetic energy gained by the flowing metal entering the mould and subsequent spreading of the fluid.
In a second aspect, the invention provides an ingot casting system.
Document AU 717 796 B2 discloses an ingot casting system according to the preamble of claim 11. According to the invention, the ingot casting system further bas the features mentioned in the characterising portion of claim 11.
Other features of the spout described above, may also apply to the casting wheel defined in the second and third aspect of the invention.
In a third aspect, the invention provides a use of the ingot casting system according to claim 16.
Preferably, in one form of the invention, each spout includes two side walls and a base, each side wall having an open edge for contacting molten metal from a launder, the initial section of the side wall extending from the open edge, being shaped so as to be substantially parallel to the initial section of side wall extending from the open edge of an adjacent spout.
Further features, objects and advantages will become apparent from the following description of the preferred embodiment and accompanying drawings:

Brief description of the drawings and preferred embodiments

Figure 1 is a schematic side view of a casting apparatus of general type used for the present invention;
Figure 2 is a schematic view of a typical ingot moulding operation;
Figure 3 is a perspective view looking down from the rear of a casting apparatus according to a first embodiment of the present invention;
Figure 4 is a detailed view of a portion of apparatus i Figure 3 but with the angle of use slightly changed;
Figure 5 is a perspective view of an embodiment of a spout used in the apparatus shown in Figure 3;
Figure 6 is a perspective view of the spout shown in Figure 5;
Figure 7 is a further perspective view of the spout shown in Figure 5;
Figure 8 is a view from below of a second embodiment of a spout used in an apparatus of the invention;
Figure 9 is a perspective view of the spout of Figure 8; and
Figure 10 is a plan view of the spout of Figure 8.

Referring now to Figures 1 and 2, a casting wheel 10 rotates about a horizontal axis 12.
The wheel has a annular member 14 with a plurality of spouts 16, fixed around its perimeter. Twelve spouts are shown for illustrative purposes in Figure 3, although any suitable number may be employed provided it complies within the constraints of the ingot mould. A feed launder 18 carries molten metal (not shown) to the wheel 10. A single uninterrupted flow stream of molten metal emerges from the discharge tip 20 of the feed launder into the open edge 22 of the annular member 14. The spouts 16 each form an opening in the rim of the wheel and direct the metal down into an ingot mould 24. The wheel and spouts are preferably integrally formed as a single piece cast iron casting. Alternatively, the wheel and spouts are produced separately and secured together to facilitate ease of replacement and repair.
The mould 24 is one of a train of like ingot moulds which are carried by a chain conveyor past the casting wheel 10. As the casting wheel rotates, the spouts index with the moulds 24 as they move along the conveyor. The speed of rotation of the wheel and the linear speed of the conveyor are matched so that each casting spout 16 tracks a respective mould 24 as it passes beneath the wheel. When a mould is directly beneath the axis 12 of the wheel, a spout 16 extends well into its associated mould 24. The rate that molten metal is supplied to the casting wheel, the speed of the conveyor and the rotational speed of the wheel are all controlled so that the molten metal reaches the desired depth in the moulds, and thus ingots of constant height are produced, no matter what the feed rate of molten metal.
Referring now to Figures 3 to 7, the annular member 114 of casting wheel 110 carries twelve spouts 116 which are bolted to the annular member 114 so their contact face 126 presses against the annular member 114. If worn or damaged, the spouts 116 are readily replaced either individually or as a set by means of the bolted fastening system.
Whereas most casting wheels in the prior art use a wheel body which has a drum structure with the spouts attached to the perimeter of the drum between opposite ends of the drum, the present invention prefers to have the drum body comprise a substantially flat annulus from which the spouts protrude from one side/face of the annulus.
Each spout is arranged around the periphery of the annular member and shaped to provide for filling of the mould with the molten metal from the launder without increasing the fluid velocity and exposed surface area of molten metal as the molten metal passes through the spout from the launder to the mould.
A spout 116 will now be described using the terms upper, lower and the like in the context of the orientation seen in Figures 5 and 6, i.e. with the spout oriented as for spout 117 (in Figure 4) at the bottom of the casting wheel and positioned for discharge for molten metal therethrough.
Each spout 116 has a sloping base 128 and a pair of side walls 130. The side walls 130 carry the face 126 which is fastened into contact with the annular member 114 of the wheel. The side walls 130 each have an open edge 135 for contacting molten metal from the launder, the initial section 137 of the side wall being shaped so that when positioned on the wheel, the initial sections 137 of adjacent side walls are substantially parallel. In this way, the adjacent and abutting side walls have an initial section which has a minimal contact angle with the flow of metal from the launder. In this way, the abutting side walls of adjacent spouts act as a flow divider to direct flow entering the casting wheel to the respective spouts.
The side walls 130 of the spout are concave shaped as they extend towards the base 128 of the spout. The concave shape of the side wall allows the base and side wall to be joined without a defined joining edge between the side wall and base, thereby lessening the turbulence in the molten metal as it enters the spout. The side walls 130 are tapered towards each other from the open edge 135 to the outlet end 134 (i.e. from the top to the bottom).
To minimise the disturbance of the molten metal stream exiting from the launder into the wheel, the slope of the spout in the region of contact with the molten metal steam is given a specific parabolic shape. The base of the spout is preferably provided with a convex curvature section in the upper portion 138 and a concave curvature section in its lower section 140. This produces an undulating shape in the base to more smoothly direct the flow of the molten metal entering the spout This convex section 138 preferably extends from the initial contact area of the base with the incoming molten metal.
Hence, the base wall 128 commences at its inlet end (top) 132 with a slope of about 45° to the horizontal (preferably within the range 35°-55°). The base wall then curves downwards towards the vertical until it reaches about 70° to the horizontal (preferably within the range 60°-80°) about midway along the base wall of the spout; and the base wall then curves towards the horizontal until it is substantially horizontal at its outlet end. (bottom) 134.
The convex shaped upper portion 138 of the base or rear wall has an approximately parabolic shape which matches the natural curvature of a freely falling stream of the molten metal pouring from the launder. The position of the launder is not shown in Figures 3 or 4. The horizontal component of the velocity of the metal issuing from the launder during normal casting rates is used to determine the curvature of the upper portion 138.
The concavely shaped lower portion 140 of the base wall 128 of the spout has a shape which smoothly redirects the metal to a horizontal flow. Horizontal flow is advantageous because it minimises splashing of the metal, exposure of more liquid metal to air, turbulence and oxidation and dross formation in the mould.
The spout is positioned as far as possible into the end of the mould from which the metal flows into the mould.
In this embodiment, in order to minimise the disturbance in the falling metal, the kinetic energy transferred to the liquid metal by way of the change in potential energy as the stream flows down is minimized. As the bottom of the launder feed trough sits lower than launder troughs in relation to conventional spouts, the height difference between the bottom of the mould and the bottom of the launder feed trough is minimised in order to minimise kinetic energy imparted to the falling metal. The metal falling into the spout is redirected along one approximately parabolic curve and then an oppositely curved approximately parabolic curve, to issue from the spout in an approximate horizontal direction. This minimizes the turbulence as the molten metal enters the mould. Rather than allowing a radial outlet ejecting fluid directly into the mould, so causing flow disruption and turbulence as the fluid jets against the mould walls, the flow is redirected to a horizontal outlet such that the liquid metal exits approximately horizontally into the mould and thus minimises the flow disturbance as it enters the mould. The spout is positioned close to one end of the mould and the liquid metal flows into the mould away from the end of the mould closest to the spout so that there is a maximum distance for the liquid metal to flow and there is minimum backwash of the molten metal.
The edge 135 (Figures 3 and 4) between spouts is reduced to be as sharp an edge as possible in order to obtain as clean a split of streams as possible when the edge 135 is passing through the flow of molten metal issuing from the launder.
Figures 8-10 illustrate a further embodiment of a spout 300 for use in the invention. As with the embodiments of Figures 5-7, each spout has a sloping base wall 328 and a pair of side walls 330. The side walls 330 carry facing edges 326 which are fastened into contact with the annular member 114 (in Figure 3) of the wheel. The side walls 330 each have an open edge 335 for contacting, dividing and directing a stream of molten metal from a launder as the casting wheel rotates. This initial section of the side wall is shaped so that when positioned on the casting wheel, the initial section of adjacent side walls (not shown) abut and are substantially parallel. Hence the initial section of the side wall in a vertical plane perpendicular to molten metal and the side wall, the side wall is substantially parallel to the flow has a minimum initial contact angle with the flow of molten metal.
The side walls 330 of the spout are concave shaped as they extend from the initial section to the base 328 of the spout. The concave shape of the side wall allows the base 328 and side walls to be joined without a defined joining edge thereby lessening turbulence in the molten metal as it enters the spout.
The base 328 has a similar shape to that described in the embodiment of Figures 5-7.
In the embodiment of Figures 9 and 10, the interior of the spout is provided with flow directing ribs 320, 322 in the base and side walls respectively which further assist in directing flow towards the outlet of the spout. These ribs are shown as distinct raised curve from the surface of the base 328 and side walls 330 but may also be a line of dimples which trace a curve. The flow directing ribs extend from the entry end of the spout towards the outlet 334.
The spout is also provided with a cover 332 extending from the outlet 334 to the facing edges 326 of the side walls. This cover prevents molten metal introduced into the spout from splashing over the top of the side walls, enabling the molten metal to be introduced into the mould in a more controlled manner. During the filling of the mould the spout outlet falls below the rising surface of the liquid metal in the mould creating an under pour situation where the turbulence is dissipated below the surface without creating additional surface thus reducing oxidation.
The area of the inlet to each spout is such that it is not choked by liquid which would cause a backup of liquid in the wheel. This also minimises the velocity of the molten metal exiting the spout. It should not be so small as to cause metal to overflow on the inlet side of the wheel for the desired flow rate.
There are no spaces between adjacent spouts in the perimeter of the wheel so that there is minimal disruption of the flow stream from the feed launder.
The casting apparatus of the invention minimises oxide generation during filling of the moulds at high production rates. The head loss from the launder feeder to the bottom of the mould is reduced and thus the kinetic energy gained by the falling molten metal is reduced. The flow stream from the feed launder directly enters the opening in the spouts due to the sharp flow divider between them.
The molten metal is delivered to the wheel through a radial opening but the downward flow of molten metal is diverted so that it exits from the spout and in an approximately horizontal direction.
Whilst the above description includes the preferred embodiments of the invention, it is to be understood that many variations, alterations, modifications and or additions may be introduced into the constructions and arrangements of parts previously described with departing from the essential features of the spirit or ambit of the invention.
It will also be understood that where the word "comprises" (or its grammatical variants) are used in this specification is equivalent to the term "includes" and should not be taken as excluding the presence of other elements or features.

Claims

A casting wheel (10, 110) for use in filling ingot moulds (24, 124) In an Ingot casting line, including
an annular member (14, 114) arranged to be mounted for rotation, and

a plurality of spouts (18, 116, 300) arranged around the periphery of the annular member (14, 114), each spout having two side walls (130, 330) and a base (128, 328), each side wall having an open edge (135, 335) for contacting molten metal from a molten metal source,
the casting wheel (10, 110) being characterised In that the initial section (137) of the side wall (130, 330) extending from the open edge (135, 335) being shaped to be substantially parallel to the initial section (137) of the side wall (130, 330) extending from the open edge (136, 335) of an adjacent spout (16, 116, 300) such that the initial section (137) of the side wall (130, 330) abuts the initial section (137) of the side wall (130, 330) of the adjacent spout.
The casting wheel of claim 1 wherein the spouts (16, 116, 300) are equally spaced around the annular member (14, 114).
The casting wheel of claim 1 wherein the side wall (130, 330) is concave shaped as It extends from the initial section (137) of the side wall (130, 330) towards the base (128, 328).
The casting wheel of claim 1 wherein the base wall (128, 328) is provided with flow directors (320) extending towards the outlet (134, 334) of the spout (16, 116, 300).
The casting wheel of claim 1 or 4 wherein the side walls (130, 330) are provided with flow directors (322) extending towards the outlet (134, 334) of the spout (16, 116, 300).
The casting wheel of claim 5 wherein the flow directors are in the form of ribs, protrusions (322) or grooves.
The casting wheel of claim 1 wherein the spout further includes a cover (332) extending from the outlet end (334) of the spout (300).
The casting wheel of claim 1 wherein the base (328) of the spout (300) converges towards the cover (332) of the outlet end (334) of the spout.
The casting wheel of claim 1 wherein the base section (128) of the spout is provided with a convex section (138) and a concave section (140) in the base In the initial contact area of the base with the molten metal entering the spout.
The casting wheel of claim 1 wherein the direction of flow of molten metal contacting the upper edges of abutting side walls Is within the plane of the initial sections (137) of the side walls (130, 330).
An Ingot casting system including
a feed system for delivering molten metal;

a casting wheel (10, 110) and a launder (18, 118) feeding the molten metal from the feed system to the casting wheel, the casting wheel being mounted to index with ingot moulds (24, 124) of a casting conveyor; the casting wheel comprising

an annular member (14, 114) arranged to be mounted for rotation, and

a plurality of spouts (16, 116, 300) arranged around the periphery of the annular member (14, 114), each spout having two side walls (130, 330) and a base (128, 328), each side wall having an open edge (135, 335) for contacting molten metal from a molten metal source,
the ingot casting system being characterised the initial section (137) of the side wall (130, 330) extending from the open edge (135, 335) being shaped to be substantially parallel to the initial section (137) of the side wall (130, 330) extending from the open edge (135, 335) of an adjacent spout (18, 116, 300) such that the initial section (137) of the side wall (130, 330) abuts the initial section (137) of the side wall (130, 330) of the adjacent spout.
The Ingot casting system of claim 11 wherein the spouts (16, 116, 300) are equally spaced around the annular member (14, 114).
The Ingot casting system of claim 11 wherein the base wall (128, 328) is provided with flow directors (320) extending towards the outlet (134, 334) of the spout (16, 118, 300).
The Ingot casting system of claim 11 or 13 wherein the side walls (130, 330) are provided with flow directors (322) extending towards the outlet (134, 334) of the spout (16, 116, 300).
The Ingot casting system of claim 14 wherein the flow directors are In the form of ribs protrusions (322) or grooves.
Use of the Ingot casting system according to any one of claims 11 to 15 for casting metal ingots including the steps of:
delivering molten metal from the launder (18, 118) to the casting wheel (10, 110), and

delivering the molten metal through each casting spout (16, 118, 300) to an ingot mould (24, 124) beneath the respective casting spout (16, 116, 300).
The use of claim 18 wherein the spouts (16, 116, 300) are equally spaced around the annular member (14, 114) with the side walls (130, 330) of each spout (16, 116, 300) abutting the side wall (130, 330) of an adjacent spout (16, 116, 300), and the direction of flow of molten metal contacting the upper edges of abutting walls is within the plane of the initial sections (137) of the side walls (130, 330).