BACKGROUND OF THE INVENTION This invention relates in general to cast vehicle wheels and in particular to a method and an apparatus for forming lightener pockets in such wheels.

Cast wheels formed from light weight metals and metal alloys are replacing steel wheels on an increasing number of vehicles. Such cast wheels provide both a reduction in weight from steel wheels and an attractive appearance.

Referring now to the drawings, there is illustrated in FIG.

1 a perspective view of a typical cast vehicle wheel, indicated generally at 10, which is formed in accordance with the prior art. The prior art wheel 10 includes an annular wheel rim 11 which is adapted to carry a vehicle tire (not shown) . The wheel rim 11 has an axial inner end

12 which is adjacent to the vehicle (not shown) when the wheel 10 is mounted thereon and an axial outer end 13 opposite from the inner end 12.

The wheel 10 further includes a circular wheel disk 14 formed across the outer end 13 of the wheel rim 11. The wheel disk 14 has an outer surface 15 which is visible when the wheel 10 is mounted upon the vehicle. Accordingly, the outer disk surface 15 is typically machined to a smooth finish and/or decorated. As shown in the sectional view of

FIG. 2, the junction of the wheel disk 14 and the rim 11 forms a sidewall 17 which is thicker than either the wheel disk 14 or the rim 11. The wheel disk 14 includes a plurality of radial spokes 18 connecting the sidewall 17 to a central wheel hub 19. The spokes 18 define a plurality of openings 20 formed through the wheel disk 14. The openings 20 allow a flow of cooling air to the vehicle brakes while reducing the weight of the wheel 10.

The hub 19 includes a recessed center portion 21 having a large central aperture 22 formed therethrough which can receive the end of a vehicle axle (not snown) .

The recessed center portion 21 also includes a plurality of smaller apertures 23 formed therethrough and spaced equally about the central aperture 22. These smaller apertures 23 receive threaded wheel lugs (not shown) for securing the wheel 10 upon a vehicle.

The wheel 10 is typically formed by gravity feeding or pressure injecting a molten metal, such as aluminum, magnesium or titanium, into a multi-piece wheel mold. A sectional view of a typical prior art multi-piece mold 30 for casting the wheel 10 is shown in FIG. 3. The individual pieces of the mold 30 are usually formed from cast iron or high carbon steel.

The mold 30 includes a bottom core 31 which supports the other mold pieces. Two or more movable side cores 32 and 33 are carried by the bottom core 31. The side cores 32 and 33 are moved in a radial direction between extended and retracted positions by a mechanism (not shown) that is conventional in the art. The side cores 32 and 33 are shown in the extended position in FIG. 3, with the side cores 32 and 33 together. When moved to the retracted position (not shown) , the core sides 32 and 33 are separated and moved apart from each other.

A movable cup-shaped top core 34 having a annular-shaped base 35 is disposed within the mold side cores 32 and 33 with the base 35 contacting the top surface of the bottom core 31, as shown to the left of FIG. 3. The bottom surface of the top core base 35 includes a plurality of radial grooves 36 formed thereacross in extended portions 36, one of which is shown to the right of FIG. 3. The radial grooves 36 are spaced equally apart about the base 35. A hub riser core 37 is secured to the top of the rop core base 35. A central vent 37A is formed through the

τ.o of tne hub riser core 37 to allow gases to escape from the mold 30 during casting operations. A core plug 38 having a plurality of slots 38A for venting gases is disposed in the central vent 37A. A*handle 38 B is attached to the top of the core plug 38. A mechanism (not shown) , that is conventional in the art, raises and lowers the top core 34 and hub riser core 37 along a central axis 39.

The mold cores 31, 32, 33, 34, 36 and 37, upon assembly, define a mold cavity 40 wherein the wheel 10 is cast. The mold cavity 40 includes an annular rim cavity 41 for casting the wheel rim 11 and a disk cavity 42 for casting the wheel disk 14. The disk cavity 42 includes radial spoke cavities 43 defined by the radial grooves 36 in the top core base 35. An annular sidewall cavity 44 for casting the wheel sidewall 17 joins the rim cavity 41 to the disk cavity 42. An annular rim riser cavity 45 is formed adjacent to the rim cavity 41. Similarly, a cylindrical hub riser cavity 46 is defined by the mold riser core 36 adjacent to the inner center of the disk cavity 42.

To cast a wheel 10, molten metal is fed by a conventional method, such as gravity or under pressure, into the mold cavity 40 through a sprue (not shown) . The molten metal flows into the disk, spoke, sidewall and rim cavities 42, 43, 44 and 41, and then fills the rim and hub riser cavities 45 and 46. As the metal contained in the mold cavity 40 cools and contracts molten metal flows from the riser cavities 45 and 46 back into the mold cavity 40 to fill any voids formed by the contraction.

Once the metal has cooled sufficiently, the top core 34 is raised and the side cores 32 and 33 moved to their retracted position to allow removal of the wheel casting from the mold 30. Additionally, when needed, an operator grasps the handle 38A and manually removes the core plug 38

to clean any excess casting metal from the core plug slots 38A.

Following removal from the mold 30, the wheel casting is subjected to conventional machining operations to form the finished wheel 10.

As described above, the sidewall 17 of the cast wheel 10 is typically thickest at its junctions with the ends of the wheel spokes 18, adding weight to the wheel 10. The corresponding thickness of the sidewall mold cavity 43 holds a large volume of molten metal which can take longer to cool than the molten metal contained in the rim and wheel disk cavities 41 and 42. When this happens, the wheel rim 11 and disk 14 can solidify before the sidewall 17. Molten metal in the rim and hub riser cavities 44 and 45 is then prevented from flowing into the sidewall cavity 43 as the metal therein contracts. As a result, voids can be formed in the sidewall 17, reducing the strength of the wheel 10 and potentially marring the wheel's appearance.

It is known in the art to form recesses, or lightener pockets, in the outer surface of the sidewall 17 adjacent to the ends of the wheel spokes 18. Such a cast wheel is described in U.S. Patent No. 4,861,113 to Imamura, et al. The lightener pockets reduce the thickness of the wheel sidewall 17 causing the molten metal in the sidewall cavity 43 to cool more rapidly than in the rim and disk cavities 41 and 42. As a result, molten metal in the hub and rim riser cavities 44 and 45 can flow into the sidewall cavity 43 as the metal therein contracts. This substantially reduces the possibility of voids being formed in the wheel sidewall 17 as the metal solidifies. Additionally, the lightener pockets reduce the weight of the wheel.

It is known in the art to use loose core pieces to form recesses in cast parts. The loose pieces are removed from the recesses after the casting is removed from the mold. When light weight metals, such as aluminum, are used

to cast such parts , the metal surrounding the loose core pieces shrinks as it cools, making it difficult to remove the loose pieces from the recesses. Thus, a separate machine is usually required to pull the loose pieces from the recesses. As an alternative, it is also known to machine the recesses into the casting. However, machining is time consuming and expensive.

SUMMARY OF THE INVENTION

This invention relates to a method and apparatus for forming lightener pockets in cast metal wheels.

The apparatus includes a wheel mold having a bottom core supporting two or more retractable side cores and a top core disposed between the side cores. The top core includes a plurality of openings formed therethrough which are adjacent to the sidewall portion of the mold cavity. A center vent formed through the top core allows gases to escape during casting operations. The top core can be raised and lowered along a mold axis which is perpendicular to the bottom core.

The apparatus also includes a spacer and guide plate which is secured to the inside of the top core. The spacer and guide plate has a plurality of guide slots formed therein which are aligned with the top core openings. A slidable pocket core is carried by each guide slot and is movable within the slot between extended and retracted positions. When in the extended position, the pocket cores extend through the top core openings and into the sidewall portion of the mold cavity to form lightener pockets in the casting. When in the retracted position, the pocket cores are fully withdrawn into the top core openings.

The apparatus further includes an anchor plate secured to the spacer and guide plate. The anchor plate supports a means for moving the pocket cores which includes a

plurality of pivotable yoke members. Each yoke member includes a pair of projecting arms. One arm of each yoke member engages a slot formed in one of the pocket cores.

The other arm of each yoke member is operatively connected to an actuator plate which can be raised and lowered along the mold axis independentally of the top core. As the actuator plate is lowered, the yoke members are pivoted in one direction, sliding the pocket cores into their extended positions. Similarly, as the actuator plate is raised, the yoke members are pivoted in a direction opposite to the first direction, sliding the pocket cores into their retracted position. Additionally, a vent tube is mounted upon the actuator plate and extends axially into the center vent. The vent tube includes a plurality of axial vent slots for venting gases from the mold cavity.

The method for forming lightener pockets in a cast vehicle wheel includes assembling the above described wheel mold with the actuator plate lowered to extend the pocket cores fully into the mold cavity and insert the vent plug into the center vent. The mold cavity is then filled with a molten metal to form a wheel casting.

After the mold and wheel casting have cooled, the actuator plate is raised while the top core remains stationary. The movement of the actuator plate causes the yoke members to pivot, retracting the pocket cores into the top core openings. Additionally, the vent tube is withdrawn from the center vent, cleaning any excess casting metal from the vent slots. After the pocket cores are fully retracted, the top core is raised clear of the casting and the side cores retracted. The wheel casting can then removed from the bottom core.

Following removal of the wheel casting, the side cores are moved together and the top core lowered into the mold. The actuator plate is then lowered, causing the yoke members to pivot back to their original position and extend

the pocket cores through the top core openings and into the mold cavity. The mold is then ready for casting another wheel.

As described above, the cast wheel produced by the method and apparatus of this invention is lighter and less likely to have voids than similar prior art wheels.

Other advantages of this invention will become apparent to those skilled in the art from the following detailed description of the preferred embodiment, when read in light of the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a cast vehicle wheel in accordance with the prior art.

FIG. 2 is a sectional view of the prior art wheel taken along line 2-2 in FIG. 1.

FIG. 3 is a sectional view of a wheel mold used to cast the prior art wheel shown in FIG. 1.

FIG. 4 is a sectional view of a cast wheel which includes lightener pockets.

FIG. 5 is a sectional view of a wheel mold which includes an apparatus in accordance with this invention for forming the lightener pockets shown in FIG. 4.

FIG. 6 is a plan view of an anchor plate included in the apparatus shown in FIG. 5.

FIG. 7 is a plan view of an actuator plate included in the apparatus shown in FIG. 5.

FIG. 8 is a sectional view of the wheel mold shown in FIG. 5 with the apparatus withdrawn.

FIG. 9 is a fragmentary sectional view of a wheel mold which includes an alternate embodiment of an apparatus for forming lightener pockets.

FIG. 10 is a fragmentary sectional view taken along line 10-10 in FIG. 9.

FIG. 11 is a fragmentary sectional view of the wheel mold shown in FIG. 9 with the apparatus partially withdrawn.

FIG. 12 is a fragmentary sectional view of the wheel mold shown in FIG. 9 with the apparatus fully withdrawn.

FIG. 13 is a fragmentary sectional view of a wheel mold which includes another embodiment of an apparatus for forming lightener pockets.

FIG. 14 is a fragmentary sectional view taken along line 14-14 in FIG. 13.

FIG. 15 is a fragmentary sectional view of the wheel mold shown in FIG. 13 with the apparatus partially withdrawn.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Referring again to the drawings, there is shown in FIG. 4 a cross sectional view of an improved wheel 50 having lightener pockets 51 formed in the inner surface of the sidewall 17 at the outer radial ends of the wheel spokes 18. As shown in FIG. 4, the pockets 51 are narrower than the spokes 18. The pockets 51 reduce the thickness of the sidewall 17 where the spokes 18 join the wheel rim 11. This reduces the weight of the improved wheel 50 and decreases the amount of time needed for molten metal to solidify when the wheel 50 is cast.

Other portions of the improved wheel 50 which are similar to portions of the prior art wheel 10 are indicated with identical numerical designators. It will be appreciated that, while the drawings and description herein show a cast "one piece" wheel 50, the invention can be practiced to form only a cast component of a multi-piece wheel such as, for example, the full front face of a wheel which is subsequently secured to a formed partial wheel rim. Thus, as used in this description and the following

claims, the term "wheel" includes not only a one piece cast wheel, but also a cast component of a multi-piece wheel.

Referring to FIG. 5, there is shown a sectional view of an improved wheel mold 60 in accordance with this invention. The improved wheel mold 60 includes an apparatus 61 for forming the lightener pockets 51 in the improved wheel 50. Components of the improved mold 60 which are similar to components of the prior art mold 30 illustrated in FIG. 3 are identified with the same numerical designators. Similarly, the mold cavities formed by the improved mold 60 also are identified with the same numerical designators used with the prior art mold 30.

The apparatus 61 includes a cylindrical spacer and guide plate 62 having an axial bore 63 formed thru the center thereof. The bore 63 receives the top of the hub riser core 37. The spacer and guide plate 62 includes a plurality of guide slots 64 formed therein extending radially across the spacer and guide plate 62, one of which is shown in FIG. 5. The guide slots 64 are equally spaced about the circumference of the spacer and guide plate 62 with one guide slot 64 corresponding to each spoke 18 of the improved wheel 50. Furthermore, the spacer and guide plate 62 is oriented within a top core 65 such that the guide slots 64 are radially aligned with the wheel spoke cavities 43. The guide slots 64 extend from the bore 63 at a downward angle from the axis 39, defining an inclined surface 66 in each slot 64. In the preferred embodiment, the angle between the inclined surface 66 and the central axis 39 is approximately 45 degrees. An opening 65A is formed through the top core 65 adjacent to the outer radial end of each of the guide slots 64. The openings 65A are radially aligned with the guide slots 64 and slant downward in FIG. 5 at the same angle with the central axis 39 as the guide slot inclined surfaces 66.

An axial bolt hole 67, one of which is shown to the left of FIG. 5, is formed through the spacer and guide plate 62 between each pair of guide slots 64. Bolts 68 pass through the bolt holes 67 and are received by threaded ^' cylindrical recesses 69 formed in the base of the top core 65 to secure the spacer and guide plate 62 thereto.

Each of the guide slots 64 carries one of a plurality of sliding core assemblies 70. In the preferred embodiment of the apparatus 61, the sliding core assemblies 70 include a generally block shaped core carrier 71. The core carriers 71 include a roll pin cavity 72 formed across the top surface thereof. The roll pin cavity 72 is transverse to the central axis 39 and has a generally rounded sectional shape. The function of the roll pin cavity 72 will be described below. A rectangular core notch 73 is formed in the bottom of the outer radial end of each core carrier 71. An aperture 74 extends through each carrier 71 from the top surface thereof to the core notch 73.

A plurality of pocket cores 75 formed from a material that is not affected by high temperatures are disposed in the core carrier notches 73. The particular core material is selected for the specific application and can include various alloys of steel, titanium and ceramics. The pocket cores 75 extend radially outward from the core notches 73 and end in tapered core tips 76. The pocket cores 75 are retained in the core carrier notches 73 by threaded fasteners 77 which pass through the carrier apertures 74 and are received by a threaded bore 78 formed through each core 75. This allows replacement of the cores 75 if they become worn or damaged. It is also possible to use pocket cores having differently shaped core tips (not shown) . This provides a capability to form differently shaped pocket recesses in the wheel without a major reconfiguration of the apparatus 60. It will be appreciated that, while the core assemblies 70 are

illustrated as being composed of two separate pieces, a single piece sliding pocket core (not shown) can be used. The pocket core tips 76 extend through the top core openings 65A and into the sidewall cavity 44, as best seen to the right of FIG. 5. Each opening 65A has the same cross-sectional shape as the pocket core 75.

Because the guide slots 64 are aligned with the top core openings 65A, each of the core assemblies 70 can be slid within the corresponding guide slot 64 and opening 65A between extended and retracted positions. The extended position is illustrated in FIG. 5 while the retracted position is illustrated in FIGS. 6 and 8.

When the core assemblies 70 are in the extended position, the alignment of the guide slots 64 with the wheel spoke cavities 43 results in the pocket core tips 76 extending into the sidewall cavity 44 at the outer radial end of the spoke cavities 43. As will be explained below, the extended core tips 76 function to form the lightener cavities 51 in the improved cast wheel 50. When the core assemblies 70 are in the retracted position, the core tips 76 are completely withdrawn within the opening 65A, as shown in FIG. 8.

The apparatus 61 also includes an anchor plate 90, of which a top plan view is shown in FIG. 6. The anchor plate 90 is carried by the spacer and guide plate 62 and is concentric with the central axis 39. The anchor plate 90 includes a cylindrical hub 91 having an axial aperture 92 formed thru the center thereof. A plurality of axial bolt holes 93 that are aligned with the space and guide plate bolt holes 66 are formed through the hub 91. The bolts 68 pass through these anchor plate bolt holes 93 to secure both the spacer and guide plate 62 and the anchor plate 90 to the top core 65.

The anchor plate 90 further includes a plurality of arms 94 extending radially outward from the hub 91. There

is one arm 94 corresponding to each guide slot 64 in the spacer and guide plate 62 and the anchor plate 90 is oriented such that the arms 94 are radially aligned with the guide slots 64. An axial slot 95 extending radially outward from the aperture 92 is formed in each arm 94. A bore 96, shown in phantom in FIG. 6, is formed through both sides of each slot 95 in a direction which is transverse to the axis 39.

A yoke member 100 is disposed in each anchor arm slot 95. Each yoke member 100 is generally V-shaped with upper and lower portions 101 and 102, respectively, extending from a central portion 103. A pivot bore 104, shown in phantom in FIG. 6, is formed through the central portion 103 transverse to the central axis 39. A pivot pin 105 is received by the pivot bore 104 and the anchor plate arm bore 96 to secure each yoke member 100 within the corresponding anchor arm slot 95. The pivot bore 104 is sized to allow rotation of the yoke member 100 about the pivot pin 105.

The yoke member upper portion 101 has a slot 106 formed therein which divides the upper portion 101 into a pair of arms 107, which are best seen in FIG. 6. A connecting bore 108, shown in phantom in FIG. 6, which is transverse to the central axis 39 extends through both arms 107.

The yoke member lower portion 103 has a generally rounded end which forms a roll pin 109. The roll pin 109 of each yoke member 100 extends into the roll pin cavity 72 formed in the core carrier 71 and engages the surface thereof. The roll pin 109 is free to rotate within the roll pin cavity 72.

The apparatus 61 further includes an actuator plate 110, which is shown in FIG. 5 immediately above the anchor plate 90 and concentric with the central axis 39. A top plan view of the actuator plate 110 is shown in FIG. 7.

The actuator plate 110 has a shape that is similar to the anchor plate 90 with a central hub 111 having an axial bore 112 formed therethrough. The upper portion of the bore 112 includes a counterbore 113, the function of which will be explained below. A plurality of arms 114 extend radially outward from the central hub 111. The actuator plate 110 has the same number of arms 114 as the anchor plate 90 and is oriented such that the arms 114 are radially aligned with the anchor plate arms 94. Each arm 114 has an axial slot 115 formed in the end thereof which extends radially inward. A bore 116, shown in phantom in FIG. 7, passes through both sides of each slot 115 in a direction which is transverse to the axis 39.

The actuator arm slots 115 receive upper end portions 120 of a plurality of movable links 121. Each movable link upper end 121 includes an upper aperture 122 formed therethrough which is aligned with the corresponding actuator arm bore 116. A link pin 123 passes through each actuator arm bore 116 and the corresponding link upper aperture 122 to secure the movable link 121 within the actuator arm slot 115. The link upper apertures 122 are sized to allow free rotation of the links 121 about the link pins 123.

The movable links 121 also have a lower end portion 124, each of which has a lower aperture 125 formed therethrough. As illustrated in FIG. 5, each link lower end portion 124 extends into the slot 106 formed in the upper portion 101 of the corresponding yoke member 100. The lower end portion 124 is positioned in the slot 106 such that the lower aperture 125 is aligned with the connecting bore 108 formed through the yoke member arms 107. A connecting pin 126 passes through the connecting bore 108 and the link lower aperture 125 to movably connect each link 121 to the corresponding yoke member 100. The

sizing of the link lower aperture 125 is such that the link 121 is free to rotate about the connecting pin 126.

The actuator plate counterbore 113 receives a flange 128 attached to the end of a solid connector rod 129, the end of which is shown in FIG. 5. The coupler rod 129 is axially movable independently of the mold top core 65 by a mechanism (not shown) . A vent tube 130 extends in the downward direction in FIG. 5 through the actuator plate bore 112, the anchor plate aperture 92 and into the spacer plate bore 63. The lower end of the vent tube 130 is slidably received in the hub riser core vent 37A. A plurality of axial vent slots 131 are formed in the lower end of the vent tube 130.

The flange 128 is retained in the counterbore 113 by a U-shaped sliding plate 132, shown partially in phantom in FIG. 7, and a sliding plate guide 133 which are mounted upon the top of the actuator plate 110. The sliding plate 132 is movable between engaged and disengaged positions with a handle 134 which is attached to the top thereof. The sliding plate guide 133 includes an axial bore 135 formed therethrough of sufficient diameter to allow passage of the flange 128. However, when the sliding plate 132 is moved fully to the left, as shown in FIGS. 5 and 7, the plate 132 is in the engaged position and covers a portion of the top surface of the flange 128. This locks the flange 128 in the counterbore 113, causing the actuator plate 110 to move with the coupler rod 129. Thus, when the locking plate 132 is in the engaged position, axial movement of the coupler rod 129 moves the actuator plate 110 towards or away from the anchor plate 90. A removable pin 136 locks the sliding plate 132 in the engaged position. When the sliding plate 132 is moved fully to the right in FIGS. 5 and 7, the plate 132 is in the disengaged position and upward axial movement of the coupler rod 129 will withdraw the flange 128 from the counter bore 113.

To cast an improved wheel 50 with lightener pockets 51, the mold 60 is assembled as shown in FIG. 5 with the actuator plate 110 fully lowered and the pocket cores 75 fully extended. Molten metal is then' fed into the mold cavity 40 through a sprue (not shown) by a conventional method such as gravity feed or pressure injection to form a wheel casting (not shown) . Gases escape from the center of the mold cavity through the vent slots 131. After the metal has cooled, the sliding core assemblies 70 must be moved to the retracted position to allow withdrawal of the top core 65 from the inside of the wheel casting. To retract the sliding core assemblies 70, the coupler rod 129 is moved axially upward in FIG. 5 while the mold top core 65 remains stationary. The movement of the coupler rod 129 moves the actuator plate 110 axially away from the anchor plate 90. As the actuator plate 110 moves axially away from the anchor plate 90, the movable links 121 pull the yoke member upper portions 101 in an upward direction in FIG. 5, causing the yoke members 100 to pivot in a clockwise direction about the pivot pins 105. As the yoke members 100 pivot, each of the roll pins 109 cooperates with the corresponding roll pin cavity 72 formed in the core carriers 71 to urge the pocket core assemblies 70 inwardly along the guide slots 64 toward the center of the spacer and guide plate 62. The coupler rod 129 is raised until the pocket core tips 76 are fully retracted into the top core openings 65A, as illustrated in FIG. 8. (For clarity, only one core carrier 71 and yoke member 100 are shown in FIG. 8.) Additionally, as the coupler rod 129 moves upward, the vent tube 130 is withdrawn from the hub riser core vent 37A, cleaning excess casting metal from the vent slots 131. Once the sliding core assemblies 70 are fully retraced, both the coupler rod 129 and the top core 65 are moved axially upward in FIG. 8 and withdrawn from

the casting. Then the side cores 32 and 33 are retracted, allowing removal of the wheel casting.

After removing the wheel casting, the side cores 32 and 33 are reclosed and the top core -65 is reinserted therebetween. Once the top core 65 is in position, the coupler rod 129 is moved axially downward in FIG. 8, causing the actuator plate 110 to move axially towards the anchor plate 90. As the actuator plate 110 moves towards the anchor plate 90, the movable links 121 push the yoke member upper portions 101 in an downward direction in FIG. 8, causing the the yoke members 100 to pivot in a counter-clockwise direction about the pivot pins 105. As the yoke members 100 pivot, each of the roll pins 109 cooperates with the corresponding roll pin cavity 72 formed in the core carriers 71 to urge the pocket core assemblies 70 outwardly along the guide slots 64. The coupler rod 129 is lowered until the pocket core tips 76 are fully extended from the top core openings 65A, as shown in FIG. 5. Additionally, as the coupler rod 129 is lowered, the lower end of the vent tube 130 is reinserted into the hub riser core vent 37A. The mold 60 is then ready for casting another wheel 50.

A wheel mold 200 including an alternate embodiment of an apparatus 201 in accordance with the present invention is illustrated in FIGS. 9 through 12. Components shown in FIGS. 9 through 12 which are similar to components of the first apparatus 61 and the prior art mold 30 described above are indicated with the same numerical identifiers.

The apparatus 201 includes the previously described actuator plate 110 which is movable axially towards and away from the top core base by the coupler rod 129. The actuator plate 110 carries a plurality of wedge shaped plates 202, one of which is shown in FIG. 9. Each plate 202 includes an upper portion 203 which is disposed within one of the actuator arm slots 115 and a lower portion 204

which extends below the actuator plate 110 in FIG. 9. The upper portion 203 has an aperture 205 formed therethrough which is transverse to the central axis 39. The link pins 123 pass through the apertures 205 to secure the plates 202 within the slots 115. The apertures 205 are sized such that the plates 202 can rotate about the link pins 123.

The actuator plate slots 115 radially orient each plate 202 within the top core 35. Accordingly, each plate 202 includes a radial outer surface 206. The lower portion of the outer surface 206 is formed at an angle "A" from the central axis 39 to define an inclined surface 208. A removable T-shaped guideway 209 is attached to each of the inclined surfaces 208 by a pair of threaded fasteners 210. The fasteners 208 pass through stepped bores 211 formed thru the plates 202 and are received by threaded bores 212 formed in the guideways 209. This allows replacement of the guideways 209 as they become worn.

The apparatus 201 also includes a plurality of retractable cores 215 formed from a material that is not affected by high temperatures. The particular core material is selected for the specific application and can include various alloys of steel, titanium and ceramics. The retractable cores 215 have generally trapezoidal-shaped bodies 216. Each core body 216 has a radial inner surface 217 which is inclined at the same angle "A" from the central axis as the plate inclined surface 208, as shown in FIGS. 11 and 12. A T-shaped groove 218 is formed in the core body 216 along the length of the core inclined surface 217. Each core body 216 also has an outer surface 219 that is parallel to the inner surface of the top core 34. A tapered core tip 220 extends radially outward from the lower portion of the core body 216. The top of the tip 220 defines an inclined surface 221 formed at an angle "B" from the central axis 39.

Each plate guideway 209 is slidably received in one of the core grooves 218, as illustrated in FIG. 10. Accordingly, the core inclined surfaces 217 can slide along the plate inclined surfaces 208. Thus, when the plates 202 move axially upward in FIG. 9, the cores 215 can slide axially downward and radially inward along the plate inclined surfaces 208. Similarly, when the plates 202 move axially downward in FIG. 9, the cores 215 can slide axially upward and radially outward along the plate inclined surfaces 208. A means (not shown) for limiting the extent of core travel along the plate inclined surfaces 208 is included in the apparatus 201.

As best seen in FIGS. 11 and 12, the wheel mold 200 includes a top core 229 having a plurality of radial slots 230 formed therethrough which extend along the top of the wheel spoke cavities 43. The slots 230 include an end portion 231 that extends axially upward into the side of the top core 229. The slot end portion 231 terminates in an inclined surface 232 formed at the angle "B" with the central axis 39. The actuator plate 110 is oriented such that the plates 202 are aligned with the top core slots 230. When the actuator plate 110 is fully lowered, as shown in FIG. 9, the bottom ends of the plates 202, guideways 209, and retractable cores 215 extend into the top core slots 230, forming the upper surface of the adjacent wheel spoke cavity 43. Similarly, the core tips 220 extend through the slot end portions 231 and into the sidewall cavity 44.

The operation of the alternate apparatus 201 will now be described. The mold 200 is assembled as shown in FIG. 9 with the actuator plate 110 fully lowered and the retractable tips 220 fully extended. Molten metal is then fed into the mold cavity 40 through a sprue (not shown) by a conventional method such as gravity feed or pressure injection. After the metal has cooled, the retractable

tips 220 must be withdrawn from the casting's lightener pockets to allow retraction of the top core 229 from the wheel casting.

To withdraw the tips 220, the coupler rod 129 is moved axially upwardly in FIG. 9, while the mold top core 229 remains stationary. The movement of the coupler rod 129 moves the actuator plate 110 axially away from the base of the top core 229, thereby raising the plates 202. As the plates 202 are raised, the core tips 220 are prevented from raising due to the core slot surface 232 and the wheel casting. Therefore, the cores 215 are forced to slide axially downward and radially inward along the guideways 209. As the cores 215 slide along the guideways 209, the plate inclined surfaces 208 exert an inwardly directed radial force upon the cores 215, pulling the cores 215 inwardly into the top core 229. Additionally, as the cores 210 are raised, the inclined surfaces of the tips 221 co-operate with the inclined surfaces 232 of the end portions of the top core slots 231 to urge the cores 210 radially inward. The combined forces exerted upon the retractable cores 215 are sufficient to break the cores 215 free from the wheel casting.

Referring now to FIG. 11, the retractable core 215 is shown in a partially retracted position. A casting 240 is shown in the mold to better illustrate the retraction of the core 215. Small directional arrows indicate the movement of the plates 202 and the cores 215 as the anchor plate 110 is raised. As the core tips 220 are retracted, lightener pockets 241 remain in the inside surface of the casting sidewall. The coupler rod 129 continues to be raised until the core tips 220 reach their fully retracted position, as illustrated in FIG. 12. Once the core tips 220 are fully retraced, both the coupler rod 129 and the top core 229 are moved axially upward in FIG. 12 and

withdrawn from the casting. Then the side cores 32 and 33 are retracted, allowing removal of the wheel casting 240 trorn the mold 200.

After removing the wheel casting, the side cores 32 and 33 are reclosed and the top core 65 is reinserted therebetween. Once the top core 65 is in position, the coupler rod 129 is moved axially downward in FIG. 12, causing the actuator plate 110 to move towards the base of the top core 229. As the actuator plate 110 moves towards the top core base, the plates 202 also move in a downward direction, as indicated by the small directional arrow in FIG. 9. As the plates 202 move downward, the plate inclined surfaces 208 cooperate with the inclined surfaces 217 of the core bodies 216 to exert an outward radial force upon the retractable cores 215. The inclined surfaces 232 of the end portions 231 of the top core slots 230 co-operate with the inclined surfaces 221 of the core tips 220 to guide the tips 220 thru the slot end portions 231 and into the sidewall cavity 44, as indicated by the small directional arrow.

As the plates 202 continue to move downward, the bottom ends of the plates 202, guideways 209, and the cores 215 are reinserted into the top core slots 230. The cores 215 continue to be urged outwardly by the plates 202 until the core outer surfaces 206 contact the inside surface of the top core 34, at which point the core tips 220 are fully extended into the sidewall cavities 44. When the core tips 220 are fully extended, the bottom ends of the plates 202, guideways 209, and the cores 215 also are fully reinserted into the top core slots 230 to form the upper surfaces of the spoke cavities 43. The mold 200 is then ready for casting another wheel 50.

A wheel mold 300 including another alternate embodiment of an apparatus 301 in ^' accordance with the present invention is illustrated in FIGS. 13 through 15.

Components shown in FIGS. 13 through 15 which are similar to components of the prior art mold 30 described above are indicated with the same numerical identifiers.

The mold 300 includes a top core 302 which has a plurality of radial slots 303 formed in the circumference of its bottom surface. The slots 303 are radially aligned with the spoke cavities 43. Each slot 303 includes a radial inner surface 304 inclined at an angle "C" with the axis 39. A bore 305 extends upward into the top core 302 from each slot 303. A permanent magnet 306 is disposed within the bore 305 and retained therein. An inclined T-shaped guideway 307 is secured to the inner surface 304 of each slot 303 with a threaded fastener 308.

A retractable core 310 formed from a material that is not affected by high temperatures is received by each top core slot 303. The particular core material is selected for the specific application and can include various alloys of steel, titanium and ceramics. The cores 310 include a tapered tip 311 and are retained in the slots 303 by the attraction of the permanent magnets 306. The core tips 311 extend into the sidewall cavity 44, as shown in FIG. 13. Each core 310 includes a radial inner surface 312 which is inclined at the same angle "C" as the inner surface 304 of the top core base slots 303. A T-shaped axial groove 313 is formed in each core inner surface 312, as shown in FIG. 14. Each groove 313 slidingly receives the guideway 307 attached to the corresponding slot 303. Thus, the cores 310 are free to slide along the guideways 307.

To use the mold 300, the cores 310 are inserted into the slots 303 with the grooves 313 receiving the guideways 307. As mentioned above, the cores 310 are retained in the slots 303 by the magnets 306. With the side cores 32 and 33 retracted, the top core 302 axially lowered into position above the bottom core 31. Then the side cores 32 and 33 are closed over the top core 302 to form the

complete mold 300. Molten metal is then fed into the mold cavity 40 through a sprue (not shown) by a conventional method such as gravity feed or pressure injection.

After the metal has cooled, the vent plug 38 is removed from the hub riser core vent 37A. Then the top core 302 is axially raised from the mold 300, as illustrated in FIG. 15 where the direction of movement is indicated by the small arrow. In FIG. 15, a wheel casting 320 is shown in the mold 300 to better illustrate the retraction of the core 310. As the top core 302 is raised from the mold 300, the retractable cores 310 are retained within lightener pockets 321 formed in the casting 320, breaking the cores 310 free from the attraction of the magnets 306 and thereby detaching the cores 310 from the top core 302. The retractable cores 310 slide downward along the guideways 307, allowing complete withdrawal of the top core 302 from the wheel casting 320.

Additionally, as the top core 302 is raised, the inclined guideways 307 act as wedges to exert a radially inwardly directed force upon each core 310. This force is sufficient to break the core tips 311 free from the lightener pockets 321, thereby releasing the cores 310 from the casting 320. Thus, while the cores 310 remain in the casting 320, there are freed therefrom and can be easily removed manually or by machine and reinstalled in the top core slots 303 for casting another wheel 50.

In accordance with the provisions of the patent statutes, the principle and mode of operation of this invention have been explained and illustrated in its preferred embodiments. However, it must be understood that this invention may be practiced otherwise than as specifically explained and illustrated without departing from its spirit or scope.