Magnesium is an attractive material for application in motor vehicles because it is both a strong and lightweight material. The use of magnesium in motor vehicles is not new. Race driver Tommy Milton won the Indianapolis 500 in 1921 driving a car with magnesium pistons. A few years after that magnesium pistons entered mainstream automotive production. By the late 1930's over 4 million magnesium pistons had been produced. Even in the early days of car production, the weight-to-strength ratio of magnesium, compared with other commonly-used materials, was well-known.
Considering the recent increase in fuel prices driven largely by increased global demand, more attention is being given to any practical and economically viable step that can be taken to reduce vehicle weight without compromising strength and safety. Accordingly, magnesium is increasingly becoming an attractive alternative to steel, aluminum and polymers, given its ability to simultaneously meet crash-energy absorbing requirements while reducing the weight of vehicle components. Having a density of 1.8 kg/L, magnesium is 36% lighter per unit volume than aluminum (density=2.70 kg/L) and is 78% lighter per unit volume than steel (density=7.70 kg/L). Magnesium alloys also hold a competitive weight advantage over polymerized materials, being 20% lighter than most conventional glass reinforced polymer composites.
Beyond pistons, numerous other vehicle components are good candidates for being formed from magnesium, such as inner door panels, dashboard supports and instrument panel support beams. In the near-term it is anticipated that components made from magnesium for high volume use in the motor vehicle might also include powertrain, suspension and chassis components.
The fact that the surface “skin” of die-cast magnesium has better mechanical properties over the bulk than more commonly used materials, thinner (ribbed) and lighter die-castings of magnesium can be produced to meet their functional requirements. Such components can have sufficiently high strength per unit area to compete with more common and heavier aluminum and plastic components. Furthermore, magnesium has considerable manufacturing advantages over other die-cast metals, such as aluminum, being able to be cast closer to near net-shape thereby reducing the amount of material and associated costs. Particularly, components can be routinely cast at 1.0 mm to 1.5 mm wall thickness and 1 to 2 degree draft angles, which are typically ½ that of aluminum. The extensive fluid flow characteristics of magnesium offers a single, large casting to replace a plurality of steel fabrications. Magnesium also has a lower latent heat and reduced tendency for die pick-up and erosion. This allows a reduced die-casting machine cycle time (˜25% higher productivity) and 2 to 4 times longer die life (from 150-200,000 to 300-700,000 shots) compared with that of aluminum casting.
However, the use of magnesium in automotive components is burdened with certain drawbacks. While magnesium is abundant as a natural element, it is not available at a level to support automotive volumes. This situation causes hesitation among engineers to design and incorporate magnesium components. On the occasion when the magnesium is selected as the material of choice, designers fail to integrate die-casting design with manufacturing feasibility in which the mechanical properties, filling parameters, and solidification profiles are integrated to predict casting porosity and property distribution.
The raw material cost of magnesium relative to other commonly used materials is also an impediment to mass implementation in the automotive industry. Current techniques for casting parts from magnesium make expanding the use of magnesium into a broader array of products less attractive. Presently, all large die-castings are produced in high pressure, cold-chamber machines where the metal is injected from one central location. This approach results in inferior material properties and waste material.
Accordingly, in order to make the use of magnesium in the production of vehicle components more attractive to manufacturers, a new approach to product casting is needed. This new approach is the focus of the apparatus set forth herein.
The adaptive and universal hot runner manifold disclosed herein finds utility in the casting of metal components in a die that is part of a metal casting apparatus. The hot runner manifold includes an inlet, two or more outlets, and a passageway that fluidly connects the inlet and the outlets. Either a hot runner injector or a metallic plug can be inserted into the outlets, the selection of one over the other depending on the design configuration of the die tool and casting. The hot runner injectors, usually in the form of straight cylinders, may have different dimensions, with a certain dimension being selected again based on the configurations of the die and casting.
A molten metal delivery component, such as a gooseneck having a shot plunger that is movable between a molten metal drawing position and a molten metal injection position, is at least partially disposed in a crucible of molten metal. The gooseneck has an inlet and an outlet. The inlet of the gooseneck is in fluid communication with the crucible. The outlet of the gooseneck is in fluid communication with the inlet of a machine nozzle. The outlet of the machine nozzle is in fluid communication with the inlet of the hot runner manifold. The hot runner manifold is in fluid communication with the mold cavity of the die by the hot runner injectors.
In operation, the user initially determines whether a hot runner injector or a plug should be inserted into the manifold outlet based upon the configurations of the die and casting. If a hot runner injector is selected, the user also selects an injector of a certain length, also as dictated by the configuration of the die. The hot runner manifold is fluidly connected with the die and with the machine nozzle. Molten metal is then drawn into the gooseneck from the crucible. The drawn molten metal is then injected from the gooseneck into and through the adaptive and universal hot runner manifold and into the mold cavity.
Other features of the apparatus and method disclosed herein will become apparent when viewed in light of the detailed description of the preferred embodiment when taken in conjunction with the attached drawings and the appended claims.
For a more complete understanding of the adaptive and universal hot runner manifold for die casting set forth herein, reference should now be made to the embodiments illustrated in greater detail in the accompanying drawings and described below wherein:
In the following figures, the same reference numerals will be used to refer to the same components. In the following description, various operating parameters and components are described for various constructed embodiments. These specific parameters and components are included as examples and are not meant to be limiting.
With reference to
The hot chamber 10 includes a casting die 12. The casting die 12 includes a cover half 14 and an ejector half 16, a plurality of hot runner assemblies 18 partially recessed within the cover half 14 of the casting die 12, a gooseneck 20, a shot plunger 21 operatively associated with the gooseneck 20, and a machine nozzle 22 fitted between the hot runner assembly 18 and the gooseneck 20. A substantial portion of the gooseneck 20 is submerged within a crucible 24 of molten metal.
Referring now to
With reference still to
The hot runner tip 38 is provided to establish thermal valving in the apparatus 10 whereby a thermal plug (shown in
The hot runner body 26 is positioned in a hot runner body cavity 40 which is recessed within the cover half 14 of the casting die 12. The hot runner body 26 is held in place by a support ring 42 which may be fastened to the cover half 14 of the casting die 12 by conventional means such as by mechanical fasteners 44 and 44′.
It is important in the operation of the apparatus 10 that the molten metal be maintained at high temperatures at all stages between the crucible 24 and the die 12. Accordingly, a series of insulators and heaters are provided to maintain the needed temperatures. To this end the hot runner assembly 18 includes both insulators and heaters. A hot runner body insulator ring 46 is fitted between the hot runner body 26 and the support ring 42. A nozzle tip insulator ring 49 is fitted between the hot runner tip 38 and the cover half 14 of the casting die 12. The hot runner body insulator ring 46 and the nozzle tip insulator ring 49 are formed from a known insulating material.
To keep the hot runner assembly 18 as uniform a temperature as possible external heaters are applied. As illustrated in
In addition or as an alternative to the use of band heaters as illustrated in
Referring now to the hot runner tip 38, this component is illustrated in sectional view in
The hot runner tip heater 54 is provided to keep the hot runner tip 38 at a preselected temperature such that the metal at the end 41 may flow freely into the mold cavity during the plunger shot but will form a solid blockage once the shot is completed. Accordingly, there is a temperature differential between the end 41 and the hot runner tip 38. This temperature differential means that the area of the opening of the hot runner tip 38 into the mold cavity will be cooler than the rest of the hot runner tip 38, thus allowing the molten metal in the immediate area of the tip to cool and become solidified locally in the area of the tip. This arrangement prevents molten metal from leaking from the cavity and back into the hot runner tip 38 at the end of the shot.
The temperature differential is dependent upon the metal being used to make the cast component. By way of example, magnesium alloy (for example, AZ91) becomes solid at 470° C. and is fully molten at temperatures over 595° C. Accordingly, the temperature of the hot runner tip 38 must be such that the metal therein is molten to allow it to flow. Conversely, the temperature at the end 41 of the hot runner tip 38 that is open to the mold cavity must be cooler than that of the rest of the hot runner tip 38 and specifically must approach, but not necessarily meet, the temperature of 470° C. at which magnesium alloy is solid. Of course, the temperature of the nozzle tip 38 may be adjusted up or down depending on the metal alloy being used.
As illustrated in
The machine nozzle 22 is illustrated in
As noted above, it is important to establish and maintain desired temperatures at all points between the crucible 24 and the die 12. Accordingly, the machine nozzle 22 is also provided with a heating element. Two forms of heating elements are illustrated in
Delivery of the molten metal from the crucible 24 to the machine nozzle 22 is accomplished by the gooseneck 20. The gooseneck 20 is detailed in sectional view in
The molten metal passageway 78 includes an inlet end 80 and an outlet end 82. The inlet end 80 is in fluid communication with the plunger cylinder 76 by way of a molten metal channel 84. The outlet end 82 terminates at a plunger molten metal outlet port 86. The plunger molten metal outlet port 86 is preferably of a conical configuration so as to mate snugly with the outer cone 68 of the machine nozzle molten metal input end 64.
The shot plunger 21 includes a piston head 88 and a plunger drive shaft 90 which selectively drives the piston head 88. The plunger drive shaft 90 reciprocates within the plunger cylinder 76. A pair of sacrificial metal rings 89 and 89′ is fitted to the piston head 88. The rings 89 and 89′ are sacrificial and are intended to be worn instead of the piston head 88 during operation. Accordingly, the need to replace the piston head 88 at regular intervals is avoided. The plunger drive shaft 90 is attached to a plunger drive mechanism 91 (shown in
The plunger cylinder 76 includes a molten metal inlet end 92. A check valve assembly 94 is fitted to the molten metal inlet end 92 at the base of the gooseneck 20 for controlling entry of the molten metal into the plunger cylinder 76 from the crucible 24. The check valve assembly 94 is needed to make repeatable castings per casting shot by assuring that the hot runner assembly 18 and the gooseneck 20 are always filled with molten metal.
The check valve assembly 94 includes an inlet end 96 and an outlet end 98. Between the inlet end 96 and the outlet end 98 of the check valve assembly 94 is a check valve ball 100. The check valve ball 100 is shown in its closed position on a check valve ball seat 102. A molten metal inlet tube 104 is optionally though preferably fitted to the inlet end 96 of the check valve assembly 94. This arrangement allows for purer molten metal to be drawn from the crucible 24 than might be drawn from the lower end of the crucible 24.
The check valve ball 100 is movable between the illustrated closed position where the check valve ball 100 is positioned on the check valve ball seat 102 and an open position (not shown) where the check valve ball 100 is lifted off of the check valve ball seat 102. Particularly, molten metal is drawn from the crucible 24 into the plunger cylinder 76 when the piston head 88 is moved in a direction away from the molten metal inlet end 92 by suction. This action urges the check valve ball 100 to be moved from its closed position, resting upon the check valve ball seat 102, to its open, molten metal-passing position (not shown) whereupon molten metal may be allowed to pass through the check valve assembly 94 unrestricted by the check valve ball 100. Once the plunger cylinder is filled with molten metal, the piston head 88 is moved in an opposite direction, that is, it is moved toward the molten metal inlet end 92. This movement forces the molten metal against the check valve ball 100 such that it is moved against and seated upon the check valve ball seat 102. The molten metal is then forced through the molten metal channel 84, into the molten metal passageway 78, through the outlet end 82 and into the machine nozzle 22.
As noted above with reference to
The gooseneck body 74′ is configured so as to eliminate the need of having to change sacrificial rings. Accordingly, the piston head 88′ is provided without sacrificial rings. This is accomplished by use of a ceramic liner 105. The ceramic liner is a sleeve that is shrink-fitted within the gooseneck body 74′. The ceramic liner 105 may be composed of a variety of ceramic materials, but preferably is composed of a silicon nitride material such as SN-240 manufactured by Kyocera. Other ceramic materials may be used as an alternative to silicon nitride. By using a ceramic liner in the gooseneck 20′ the metal-to-metal wear of the arrangement of the gooseneck 20 is eliminated.
Regardless of whether the gooseneck 20 or the gooseneck 20′ is used, once the molten metal enters the machine nozzle 22 its movement is continued by the action of the piston head 88 (or 88′) through the machine nozzle 22 and into the hot runner body 26. Passing through the hot runner body 26, the molten metal next proceeds through the hot runner tip 38 and into a cavity in the die 12. This procedure represents the most fundamental aspect of the invention. The molten metal proceeds from the gooseneck 20 through to the casting die 12 with both the temperature and the rate of flow being fully controlled by external operations (not shown).
However, the method and apparatus disclosed herein may be used in more complex applications than the single injector arrangement shown in
With reference to
With reference to both
A key aspect of the versatility of the manifold 106 according to the present invention resides in the adaptability of the manifold 106 to a variety of castings. This adaptability is based on the ability of the hot runner injectors to be interchanged or removed entirely and replaced with a plug to achieve cost saving, less machine downtime, and quality casting per molten metal filling pattern. Specifically, and still referring to
As shown, the hot runner injectors 146 . . . 152 are not necessarily of the same length. In addition, a plurality of plugs 162, 164, 166, 168 are fitted to the unused fluid passageways 114, 118, 120, 126 respectively.
The arrangement shown in
A sectional view of the manifold 106 is shown in
The use of the manifold 106 with a die set comprising a cover die 172 and an ejector die 173 is illustrated in
In operation, the desired number and lengths of hot runner injectors are selected based on the number and length of the hot runner injector-passing ports. The key point is to have the optimal arrangement of hot runner injectors to achieve a fine filling pattern and quality casting. Each of the selected hot runner injector is attached to the manifold 106, preferably by threading, although other measures of attachment may be used in the alternative. Plugs are inserted into the unused hot runner injector-passing ports.
The foregoing discussion discloses and describes an exemplary embodiment of the adaptive and universal hot runner manifold for die casting and method of use disclosed herein. One skilled in the art will readily recognize from such discussion, and from the accompanying drawings and claims that various changes, modifications and variations can be made therein without departing from the true spirit and fair scope of the disclosed method and apparatus as defined by the following claims.
This invention was made with United States Government support awarded by the following program, agency and contract: NIST Advanced Technology Program, the United States Department of Commerce, Contract No. 70NANBOH3053. The United States has certain rights in this invention.
Number | Name | Date | Kind |
---|---|---|---|
1964324 | Korsmo | Jun 1934 | A |
3270383 | Hall et al. | Sep 1966 | A |
3652073 | Lewis | Mar 1972 | A |
4408651 | Smedley et al. | Oct 1983 | A |
4690198 | Hardey et al. | Sep 1987 | A |
5295806 | Gunther | Mar 1994 | A |
5299623 | Yaffe et al. | Apr 1994 | A |
5983979 | Miki | Nov 1999 | A |
6305923 | Godwin et al. | Oct 2001 | B1 |
6405784 | Takizawa et al. | Jun 2002 | B2 |
6405785 | Gellert et al. | Jun 2002 | B1 |
6634412 | Murray et al. | Oct 2003 | B1 |
6745821 | Wilson | Jun 2004 | B1 |
20020121355 | Bigler et al. | Sep 2002 | A1 |
20040144516 | Liu | Jul 2004 | A1 |
20050226956 | Fischer et al. | Oct 2005 | A1 |
20050238748 | Jenko | Oct 2005 | A1 |
20050255189 | Manda et al. | Nov 2005 | A1 |
20060228442 | Fischer et al. | Oct 2006 | A1 |
Number | Date | Country | |
---|---|---|---|
20080164290 A1 | Jul 2008 | US |