RISER SLEEVE WITH AIR GAP

Abstract

A riser sleeve (100) for use in a foundry molding operation has cylindrical body in which the side wall (14) that may be untapered or that may taper uniformly from the bottom to the top (12) of the body. The riser sleeve is characterized by a plurality of cavities (102) are formed on the side wall, extending from the top in an axial direction of the body. These cavities provide air gaps when the riser sleeve is inserted into a mold, decreasing heat loss at the interface between the riser sleeve and the mold.

Description

TECHNICAL FIELD

The disclosed embodiments of the present invention relate to a riser sleeve for use in the casting of molten metal, and, in particular, to a riser sleeve that is shaped around an exterior surface thereof to provide closed cavities when the riser sleeve is inserted into a riser cavity of a foundry mold. In an even more particular embodiment, the cavities are positioned in the sleeve to run as generally vertical depressions along the sleeve exterior when the riser sleeve is operationally positioned in the foundry mold.

BACKGROUND OF THE ART

As described in U.S. Pat. No. 6,640,874, among other prior art references, riser sleeves and their use are well known in the prior art. A riser sleeve operates in a foundry mold as a conduit and as a reservoir. When molten metal is poured into a preformed cavity shaped in the nature of the product being formed, a portion of the poured metal flows into and accumulates in the riser. As the metal in the cavity solidifies, shrinkage of the solidified metal in the mold would result in dimensional changes and possibly internal cavities, in the absence of a riser.

The loss of heat from the metal in the riser cavity primarily occurs at the interface of the metal with the mold. By strategically placing one or more riser sleeves in the foundry mold, with each riser sleeve in gravity-feed liquid communication with the cavity, and by maintaining the molten metal in the sleeve in its molten state, at least preferentially to the metal in the casting, molten metal is available after the pour to flow from the sleeve into the mold, offsetting the shrinkage. If this objective is not achieved, the metal in the riser sleeve simply solidifies and becomes another appurtenance to the casting that needs to be removed in finishing the product.

The riser sleeves themselves are not a part of the finished casting. Once the casting has properly cooled, the risers are removed as a part of the foundry mold.

It has been an ongoing effort in the casting industry to provide riser sleeves that achieve their objective in an effective manner. The continuing nature of this effort speaks loudly about the need for additional improvement.

Thus, there exists a need in the prior art for an improved riser sleeve.

SUMMARY OF THE INVENTION

This and other unmet advantages are provided by a riser sleeve for use in a foundry molding operation. The sleeve has a body with an outside wall that extends from a bottom to a top of the body. The riser sleeve is characterized by a plurality of cavities that are formed on the side wall, extending from the top in an axial direction of the body.

In some instances, the body is cylindrical. In other instances, the body is frustoconical, preferably with a diameter that decreases uniformly from the bottom to the top.

In some instances, each of the plurality of cavities is preferably substantially semi-cylindrical, each cavity having an axis that is preferably aligned along a virtual circumferential area of the outside side wall that does not comprise the cavities. In some of these instances, each cavity is characterized by a radius, such that the axes of adjacent cavities are spaced apart by a distance of at least four radii around the circumference of the riser sleeve. In some of these, each cavity preferably subtends an angle in the range of from about 120° to about 180°, as measured from the axis of the cavity.

In some instances, each cavity extends along the outside wall over a majority of a distance from the top towards the bottom, but each cavity terminates above the bottom.

In some instances, the plurality of cavities are substantially uniformly spaced around a circumference of the body.

In some instances, the body is substantially hollow, with an interior wall or surface that is cylindrical or that tapers from bottom to top in a manner that corresponds to the side wall.

BRIEF DESCRIPTION OF THE DRAWINGS

A better understanding of the disclosed embodiments will be obtained from a reading of the following detailed description and the accompanying drawings wherein identical reference characters refer to identical parts and in which:

FIG. 1 is a perspective view of a formed riser sleeve as known in the prior art before imparting the air gaps of the claimed invention;

FIG. 2 is a perspective view of the formed riser sleeve of FIG. 1, after the air gaps have been formed thereon; and

FIG. 3 is a perspective view of a riser sleeve of the claimed invention, shown in partial sectional view on a mold pattern.

DETAILED DESCRIPTION

In general, riser sleeves are one of two types. Blind riser sleeves comprise a hollow dome-shaped riser sleeve, which is open at the bottom. Open-top riser sleeves are generally annular shaped, that is, open at both top and bottom. Blind riser sleeves are more expensive to manufacture. Their use is typically reserved to special applications. Open-top riser sleeves, on the other hand, allow the casting operator to see the progress of the cast by visualizing the level of the molten metal in the riser sleeve. For purposes of this patent specification, the term “riser sleeve” is used generically to apply to both types, unless there is specific reference to one of the types.

The riser sleeves may be inserted into the mold cavity after the mold is formed. This is generally referred to as an insertable sleeve. The riser sleeve may also be placed on the pattern and the mold formed around the sleeve to create the riser cavity. This is generally referred to as a “ram-up” sleeve). Generally in the prior art, the wall of the sleeve will have a uniform thickness and fit tightly into the mold with negligible gap between the sleeve and the mold.

Again, speaking still in a general manner, riser sleeves are manufactured from heat insulating materials, with the intent of slowing the solidification of the molten metal contained within the riser sleeve before it passes to the cavity in the foundry mold. Alternatively or additionally, the riser sleeves may be made from exothermic materials intended to generate heat to maintain fluidity of the molten metal. Typical riser sleeves are manufactured from refractory materials, including man-made fibers. They may include fuels such as aluminum or silicon which are used to produce their respective heat insulating oxides during an exothermic reaction within the riser sleeve. Properties sought to be optimized in riser design include low density and high porosity, as these facilitate the heat insulating properties.

Feeding aids are used to slow and control the solidification of the riser. These may be insulating or exothermic sleeves or “hot topping”. A sleeve consists of material that lines at least part of the riser cavity, to slow the heat loss from the riser by providing insulation or additional heat input from an exothermic material or both. Hot toppings are insulating or exothermic material used to cover the top of the riser after pouring where the riser is open through the top of the mold.

Sleeves can be manufactured from a variety of different materials including refractory fibers, sand, hollow refractory spheres, as well as other refractory materials. Refractory fiber sleeves are typically formed by depositing the fiber and other ingredients onto a wire mesh form that creates the internal dimensions of the sleeve. The fiber and other ingredients are in a water-based slurry and are deposited on the form by drawing a vacuum on the interior of the form. This creates a sleeve with a somewhat rough external surface. Sleeves made from sand or from hollow spheres plus other ingredients can be formed by blowing a mixture of the dry ingredients and a liquid foundry binder into a mold/corebox and curing the binder in the mold to create a solid sleeve with both internal and external shapes formed by the mold. The walls of a riser sleeve made from sand or hollow spheres will tend to be more uniform than those made from fibrous materials and this may make the sand/hollow sphere riser sleeves more amenable to the implementation of the inventive concept.

The insulating or exothermic properties of a riser sleeve is predominantly determined by the material used to create the sleeve. For instance, a fiber refractory sleeve will typically have a lower density than the mold material and provide insulation because of lower heat capacity and thermal conductivity. A sand exothermic sleeve may contain a relatively high percentage of exothermic material, typically thermite of a mixture of metallic aluminum powder and iron oxide. When the riser is filled with molten metal the thermite ignites and provides a secondary heat source for the riser.

Turning attention now to FIG. 1, a perspective view of a riser sleeve blank 10 is shown. This sleeve blank 10 is shown as being slightly frusto-conate, with a diameter that decreases uniformly and monotonically from a bottom or base to a top 12. Both the top 12 and the base are depicted as being normal to a central axis of the blank 10. Depending upon the application, it may be desirable in some applications to round off the top surface into more of a bullet point shape, especially when the riser sleeve will be of the blind type that will be inserted in a “ram up” manner. Although riser sleeve blank 10 is of the blind-type, it has the flattened top 12.

It should be clear from the depicted embodiment that the sleeve blank 10 could easily be cylindrical, with a consistent diameter from top to base. The sleeve blank 10 shows a smooth and consistent texture to the outside walls 14 and can be produced from a variety of different materials.

A perspective view of an embodiment 100 of a riser sleeve having the inventive concept is provided in FIG. 2. In the specific embodiment 100, which is also depicted as being of the blind-type, there are ten depressions or cavities 102 formed on the outside wall 14. This plurality of cavities 102 is depicted as arranged in a substantially uniform spacing around the circumference of the outside wall 14, although the uniform spacing is not considered critical to the efficacy of the riser sleeve being formed. While the body of the embodiment 100 is depicted as cylindrical, it will be known to those of skill that some casting situations will require other shapes, such as an oval or flat-faced shape, but that these shapes can also be formed with a plurality of cavities in the same manner as is depicted with the cylindrical embodiment.

The depressions or cavities 102 on the embodiment 100 are depicted as being substantially semi-cylindrical. An axis of each semi-cylindrical cavity 102 is generally aligned along the outside wall 14, with the effect being that the respective axes reflect the slightly conate or generally cylindrical nature of the overall riser sleeve 100. A top end of each cavity 102 is open and provides a “scalloped” circumference to the top 12. The cavities 102 are depicted as extending a substantial portion of the height of the riser sleeve 100 from the top of the sleeve in an axial direction of the sleeve, but each cavity clearly terminates above the base. This results in a cylindrical ring around the base of the riser sleeve, with the intent of forming a tight seal with the mold, preventing liquid metal from flowing into the cavities during the pour.

With regard to the size and number of the cavities 102, it may be expected that, in the case of semi-cylindrical cavities having a radius R, the axes of adjacent cavities will be spaced apart by a distance of at least 4R around the circumference of the riser sleeve 100. Worded somewhat differently, at least one-half of the original surface of the outside walls 14 will be preserved for contact with the mold, although it may prove to be desirable to have about 40% of the side wall removed in the creation of the cavities.

As depicted, the cavities 102 are semi-cylindrical, that is, the axis of the cavity is effectively located along the surface or outside wall 14, and an angle of approximately 180° is subtended between adjacent edges of a given cavity. In general, it may be more preferred to include less than 180°, that is, to position the axis outside of surface 14, than to have more than 180° of the cylinder subtended, which would result when the axis would be positioned inside of surface 14. This would prevent forming a thin re-entrant surface along the edges of the cavity that would be subject to breakage. In any case, the subtended portion of the cylinder would be at least 120° and in almost all cases will be less than 180°.

By imposing these cavities 102, a corresponding number of closed air gaps are formed between the sleeve and the mold when the sleeve is inserted into the mold. These cavities 102 will trap air in them. The air-filled cavities 102 would have very low heat capacity and thermal conductivity compared to both the mold material and the sleeve. They will further reduce the contact area between the mold and the sleeve, reducing conductive heat loss. The cavities 102 also provide additional insulation. This could result in better performance by the sleeve and would also result in lower sleeve weight and material cost, as the primary thickness of the riser sleeve blank would not be increased in order to impose the cavities.

While not fully tested, it is expected that the sleeve 100 can improve feeding efficiency and allow the use of smaller risers and sleeves for improved casting yield.

The use of the riser sleeve 100 is shown in a perspective schematic manner in FIG. 3, in which the riser sleeve is shown mounted on a mold pattern 40, and, more particularly, on a mounting plug 42 of the mold pattern. For “ram-up” applications where the riser sleeve is placed directly on the pattern and molding sand is compacted around the sleeve to form the sleeved riser, a paper, cardboard, plastic film, or similar material covering can be placed over the sleeve, with the paper or similar material forming the outside surface of the air filled cavity and preventing infiltration by the molding sand as the mold is rammed into position.

As clearly shown in FIG. 3, the riser sleeve 100 will be significantly hollow, either due to the process by which it is initially formed or from the removal of material. The interior surface 104 will have preferably have a taper from bottom to top 12 that will correspond to that of outer surface 14, except for the cavities, which are found only on the outer surface.

The depicted riser sleeve having the inventive features is a so-called “blind” riser sleeve as described above. However, it is well within the skill of one of ordinary skill in the art to apply the teachings of the present specification to provide the same inventive features on an open-top riser sleeve.

Having shown and described a preferred embodiment of the invention, those skilled in the art will realize that many variations and modifications may be made to affect the described invention and still be within the scope of the claimed invention. Thus, many of the elements indicated above may be altered or replaced by different elements which will provide the same result and fall within the spirit of the claimed invention.

Claims

1. A riser sleeve for use in a foundry molding operation, the sleeve comprising: a body having a outside wall that extends from a bottom to a top of the body, anda plurality of cavities formed on the outside wall, extending from the top in an axial direction of the body.

2. The riser sleeve of claim 1, wherein the body is cylindrical.

3. The riser sleeve of claim 1, wherein the body is frustoconical.

4. The riser sleeve of claim 2, wherein each of the plurality of cavities is substantially semi-cylindrical, each cavity having an axis that is aligned along the outside wall.

5. The riser sleeve of claim 4, wherein each cavity is characterized by a radius, such that the axes of adjacent cavities are spaced apart by a distance of at least four radii around the circumference of the riser sleeve.

6. The riser sleeve of claim 4, wherein each cavity subtends an angle in the range of from about 120° to about 180°, as measured from the axis of the cavity.

7. The riser sleeve of claim 1, wherein each cavity extends along the outside wall over at least a majority of a distance from the top towards the bottom, terminating above the bottom.

8. The riser sleeve of claim 1, wherein the plurality of cavities are substantially uniformly spaced around a circumference of the body.

9. The riser sleeve of claim 1, wherein the body is substantially hollow, with an interior wall or surface that corresponds in shape to the outside wall, less the plurality of cavities.

10. The riser sleeve of claim 3, wherein the body has a diameter that decreases uniformly from the bottom to the top.

11. The riser sleeve of claim 3, wherein each of the plurality of cavities is substantially semi-cylindrical, each cavity having an axis that is aligned along the outside wall.

12. The riser sleeve of claim 10, wherein each of the plurality of cavities is substantially semi-cylindrical, each cavity having an axis that is aligned along the outside wall.

13. The riser sleeve of claim 11, wherein each cavity is characterized by a radius, such that the axes of adjacent cavities are spaced apart by a distance of at least four radii around the circumference of the riser sleeve.

14. The riser sleeve of claim 12, wherein each cavity is characterized by a radius, such that the axes of adjacent cavities are spaced apart by a distance of at least four radii around the circumference of the riser sleeve.

15. The riser sleeve of claim 12, wherein each cavity subtends an angle in the range of from about 120° to about 180°, as measured from the axis of the cavity.

16. The riser sleeve of claim 12, wherein each cavity extends along the outside wall over at least a majority of a distance from the top towards the bottom, terminating above the bottom.

17. The riser sleeve of claim 16, wherein the plurality of cavities are substantially uniformly spaced around a circumference of the body.

18. The riser sleeve of claim 17, wherein the body is substantially hollow, with an interior wall or surface that corresponds in shape to the outside wall, less the plurality of cavities.