The present invention relates generally to methods for improving the thermal treatment of castings during thermal treatment cycles such as solution heat treatment, quenching and aging, and in particular to a method for improving the thermal treatment of castings formed in an HPDC process.
Historically, the thermal treatment of thin wall aluminum alloy castings that have been formed in a high pressure die cast (HPDC) process, so as to improve their metallurgical properties and performance in high-demand applications, is problematic and often results in defective parts and high scrap rates. For example, these types of castings often have complex shapes, surface features, apertures, and variations in their cross-sectional thickness that make it difficult to apply thermal treatments to the castings in a uniform manner during a typical high-volume production process. It has been found that unevenly-applied thermal treatments can often create large temperature gradients through the thickness or across the expanse of the alloy material during thermal treatment, resulting in dimensional distortions that remain set within the casting material after the thermal treatments are completed and the casting has returned to an ambient equilibrium temperature. In addition, the casting can also be particularly prone to distortion if not properly supported during thermal treatments, such as a solution heat treatment cycle, that raise its temperature to elevated levels that soften the alloy material and allow the thin wall portions to sag under their own weight or to deflect or buckle under the weight of heavier overlying portions. Whether caused by temperature gradients or by sagging or buckling, if the dimensional distortion of the casting after thermal treatment exceeds predetermined tolerances, the casting is generally scrapped.
Previous attempts to control the sagging, deflection or buckling created during solution heat treatments through improved casting support systems include full position fixtures, not shown but known to one of skill in the art, that are tightly or with close tolerances clamped around the castings shortly after their removal from the die, and which then travel with the castings throughout the thermal treatments to rigidly support and constrain the castings so as to reduce sagging and other distortions that could pull the metallic parts out of dimensional tolerance. However, full position fixtures become more difficult to create with increased complexity and variation in the castings, and by their very presence can often impede or block the flow of thermal fluids to portions of the casting material, thereby exacerbating the temperature gradients within the part. This can lead to the formation of internal stresses that cause the castings to spring out of shape when the full position fixtures are removed after the thermal treatments are complete.
In addition, previous attempts to control the application of thermal fluids (e.g. heated air, cooling air, water, oil, glycol, and the like) to the castings during the thermal treatments that apply large and/or rapid temperature changes to the part (e.g. solution heat treatment and quenching), so as to reduce or avoid the creation of large temperature gradients within and across the part, have also meet with limited success.
Briefly described, one embodiment of the present disclosure comprises a method for improving the thermal treatment of castings, as especially high volume production castings, for enhanced metallurgical properties. The method includes the steps of obtaining a plurality of untreated castings of a given casting design, followed by capturing three dimensional surface measurements of the untreated castings to determine a baseline three dimensional shape for the castings. The method also includes obtaining a first support fixture having a first support profile that is configured to support the castings within one or more thermal treatment zones, and then applying a thermal treatment protocol to a first casting that is supported on the first support fixture within the one or more thermal treatment zones. The method further includes capturing a three dimensional surface measurement of the first casting to determine its post-treatment three dimensional shape, comparing the baseline shape with the post-treatment shape of the first casting, and then identifying one or more correctable dimensional distortions in the first casting that are the result of inadequate support or positioning during the thermal treatment protocol. The method then continues with the steps of obtaining a second support fixture that is configured to support the castings with a second support profile that is different from the first support profile, applying the thermal treatment protocol to a second casting that is supported on the second support fixture. The method further includes the steps of capturing a three dimensional surface measurement of the second casting to determine its post-treatment three dimensional shape, comparing the baseline shape with the post-treatment shape of the second casting, and then identifying a reduction in a dimensional distortion to verify that the dimensional distortion is at least partially due to inadequate support or positioning during the thermal treatment protocol.
Another embodiment of the disclosure comprises a method for improving the thermal treatment of castings for enhanced metallurgical properties that includes the steps of obtaining a plurality of untreated castings of a given casting design, followed by capturing three dimensional surface measurements of the castings to determine a baseline three dimensional shape for the castings. The method also includes obtaining a support fixture having an open lattice construction with a plurality of top edges that together define an open support surface that is substantially complementary with an underside surface of the castings, and that is configured to loosely support the castings atop the lattice and orientate the castings in space above the support fixture. The method further includes applying a thermal treatment protocol to a first casting supported on the support fixture, capturing a three dimensional surface measurement of the first casting to determine its post-treatment three dimensional shape, comparing the baseline shape with the post-treatment shape of the first casting, and then identifying a dimensional distortion in the first casting.
When the correctable dimensional distortions in the first casting are the result of inadequate support or positioning during the thermal treatment protocol, the method can continue with the steps of obtaining a second support fixture including an open lattice having a plurality of top edges that together define a second open support surface that is different from the first support fixture, applying the thermal treatment protocol to a second casting supported on the second support fixture, capturing a three dimensional surface measurement of the second casting to determine its post-treatment three dimensional shape, comparing the baseline shape of the second casting with the post-treatment shape, and identifying a reduction in the dimensional distortion in the second casting to verify that the dimensional distortion is at least partially due to inadequate support or positioning during the thermal treatment protocol.
Alternatively, when the correctable dimensional distortions in the first casting are the result of high gas content in the alloy material, the method can continue with the steps of applying a second thermal treatment protocol to a second casting supported on the support fixture, capturing a three dimensional surface measurement of the second casting to determine its post-treatment three dimensional shape, comparing the baseline shape of the second casting with the post-treatment shape, and identifying a reduction in the dimensional distortion in the second casting to verify that the dimensional distortion is at least partially due high gas content in the alloy material. In one aspect the second thermal treatment protocol further comprises reducing the period of time that the second casting experiences temperatures that are above a predetermined silicon solution temperature of the alloy material.
These and other aspects, features, and advantages of the methods of this disclosure will become apparent to the skilled artisan upon review of the detailed description set forth below taken in conjunction with the accompanying drawing figures, which are briefly described as follows.
Those skilled in the art will appreciate and understand that, according to common practice, various features of the drawings discussed below are not necessarily drawn to scale, and that dimensions of various features and elements of the drawings may be expanded or reduced to more clearly illustrate the embodiments of the present disclosure described herein.
The following description is provided as an enabling teaching of exemplary embodiments of methods and systems for improving the thermal treatment of castings for enhanced metallurgical properties. Those skilled in the relevant art will recognize that changes can be made to the embodiments described, while still obtaining the beneficial results. It will also be apparent that some of the desired benefits of the embodiments described can be obtained by selecting some of the features of the embodiments without utilizing other features. In other words, features from one embodiment or aspect may be combined with features from other embodiments or aspects in any appropriate combination. For example, any individual or collective features of method aspects or embodiments may be applied to apparatus, product or component aspects, or embodiments and vice versa. Accordingly, those who work in the art will recognize that many modifications and adaptations to the embodiments described are possible and may even be desirable in certain circumstances, and are a part of the invention. Thus, the following description is provided as an illustration of the principles of the embodiments and not in limitation thereof, since the scope of the invention is to be defined by the claims.
Illustrated in
Illustrated in
The less equipment-intensive high pressure die cast (HPDC) process holds the promise of providing these same complex castings at higher rates and reduced casting costs; however, the HPDC process has its own characteristics and drawbacks. For instance, gases and vaporized liquids that are present within the mold cavity when the molten metal is introduced under high pressure and velocity can often be taken up by the alloy material, resulting in a solidified casting that contains a greater amount of dissolved gases than those formed using other casting methods. These dissolved gases can often be distributed unevenly or irregularly throughout the part, forming regions of increased concentration. The dissolved gases tend to migrate out of solution during heat treatment to form micro-bubbles within the alloy material that, in low concentrations, are relatively innocuous. In regions of increased concentration, however, the micro-bubbles can combine during prolonged periods at elevated temperatures to form, depending their location within the structure of a particular casting, laminar cracking defects and blisters near the surface that mar its finish, as well as larger bubbles or porosity internal to the casting that can manifest as more remote and generalized dimensional distortions at the outer surfaces. While the surface defects are generally easy to view and identify, it can be difficult to distinguish dimensional distortions resulting from interior porosity from dimensional distortions resulting from inadequate support or positioning during the thermal treatment protocols described above. This can be particularly problematic for thin-wall castings having complex shapes, such as the shock tower 12 shown in
According to common practice, the castings will generally be placed on the support surface 28 of the casting tray 20 in their most stable orientation so that they will not shift, roll, or slide off the support tray while the passing through a heat treatment furnace, as it can be prohibitively expensive to shut down a heat treatment furnace during a product run and allow it to cool in order to retrieve a fallen casting. This type of casting support system 20 has been proven effective over time for many types of castings, include heavy or thick-wall castings such as engine blocks, head covers, and transmission casings, that are self-supporting and readily exposed atop the upper support surface 28. For complex thin-wall castings, however, such as the shock tower 12 shown in
In one aspect the casting 100 of
In general, the casting 100 can be of a type intended for high volume production using a manufacturing process that includes initial formation in an HPDC process, followed by one or more thermal treatments to provide the parts with a desired range of metallurgical properties necessary for structural performance in a particular application. Prior to commencement of full-scale production, however, it may be desirable to determine both a thermal treatment protocol and a casting support configuration for the castings 100 that will reduce or mitigate the above-described problems with the HPDC process, and thereby produce cast parts with enhanced metallurgical properties at reduced scrap rates, and with improved yield ratios and efficiency. Alternatively, it may be desirable to improve or update an existing high volume production run of the castings 100 for the same reasons.
Toward those ends, one method of the present disclosure can commence with obtaining a plurality or sample set of untreated test castings 100 of a given production casting design (i.e. the shock tower 102). In one aspect this could be a set of prototype castings that are formed during development of the dies that will be used during full-scale production, while in another aspects the sample set of test castings 100 can be production castings that have been withdrawn from an existing manufacturing process prior to a heat treatment stage. In either case the castings 100 are allowed to cool or rest for a period of time within a temperature controlled environment, and to reach a state of thermal equilibrium at a predetermined measurement temperature that is generally near or at ambient or room temperature.
Upon reaching thermal equilibrium at the measurement temperature, digital three dimensional (3D) measurements of the full surface geometry of the exterior surfaces of the test castings 100 can then captured and stored in digital format in the memory of an electronic processor-based computer system. One such measurement system for capturing the 3D surface measurement is the ATOS Triple Scan™ surface measurement system provided by GOM mbH™, headquartered in Braunschweig, Germany. Generally, 3D measurements of both the topside exterior surfaces 104 and underside exterior surfaces 106 of the test castings 100 can be captured, processed and stored to determine a digitized three dimensional baseline exterior shape for the castings in the sample set. In some aspects any internal cavities or volumes that are of sufficient size and with sufficient access to receive the sensing head of the measurement system can also be captured and stored in the computer system. Furthermore, in one aspect the three dimensional surface measurement for each of the untreated test castings 100 can also be compared to identify and compensate for any inconsistencies in the casting process.
The method further includes obtaining a customizable support fixture that is configured to support the castings 100 with a first support profile within one or more thermal treatment zones or systems. One embodiment of a casting support system 110 that includes a customizable support fixture 140 is illustrated in
It will be appreciated that the tray 120 is generally configured to ride on chains, a roller conveyor, or similar transfer mechanism while carrying the castings 100 through one or more thermal treatment zones, such as a furnace, a quench system, an oven, or the like, to expose the castings to the thermal treatments. In some embodiments the tray 120 can be used within a continuous process in which multiple trays 120, each supporting a group of castings 100, are carried in sequence through the thermal treatment zones. In some aspects the tray 120 can ride directly on the rollers or chains, while in other aspects the tray can include an underlying support structure (not shown) that provides an interface between the transfer mechanism and the tray 120. In other embodiments where the thermal treatments are applied in discrete batch-type furnaces or quench systems, the trays 120 may be adapted for conveyance by robotic arms, fork lift trucks, shuttle carts, or similar manipulators that move the trays and groups of castings between thermal treatments.
The casting support system 110 further includes one or more customizable support fixtures 140 attached to the tray 120 that support and align the castings 100, such as the exemplary automotive vehicle shock towers 102 shown in the
Although not limited to any particular type of casting, the casting support system 110 can be particularly suitable for supporting thin wall aluminum alloy castings that have been formed in an HPDC process by reducing many of the problems associated with the thermal treatment of these parts described above. For instance, the customizable support fixtures 140 can be configured to support each casting 100 at key locations during high temperature solution heat treatments while still providing direct access by the thermal fluids to nearly all of the surfaces of the casting. In this way the casting support system 110 can prevent sagging while facilitating uniform and evenly-applied thermal treatments that reduce the internal temperature gradients across the treated part as the overall temperature of the part is being raised or lowered
Additional aspects of the casting support system 210 can be seen in
As illustrated in the cross-sectional side view of the casting support system 210 and casting 200 provided in
The casting support system 210 of the present disclosure can overcome this difficulty by independently supporting each section of the casting, including each of the heavy portions 207 or thick wall portions 205 as well as the thin wall portions 203, at key locations 248 across the underside of the casting 200. This can be accomplished by providing the top edges 246 of the support plates 242 with irregular shape profiles along their lengths that are at least partially complimentary with the irregular underside surfaces 206 of the casting. Once the support plates are assembled, and optionally interconnected, together to form the lattice 250, the plurality of top edges 246 of the lattice 250 define an open support surface, or support profile, that is substantially complementary with, although not necessarily conforming to, the underside surface 206 of the casting. As will be understood one of skill in the art, the support surface is “open” because it is not continuous, and instead is only defined by the top edges 246 of the support plates 242 that form a pattern or grid of narrow contact lines underneath the casting. The remainder, majority portion of the “surface” is imaginary and open to the polygonal-shaped flow areas or channels defined by the vertical support plates, and that can guide separate flows of thermal fluid upward from the tray opening 226 to the underside surface 206 of the casting 200.
The support surface defined by the plurality of top edges 246 of the support plates 242 can be substantially complimentary with the underside surface 206 of the casting 200 in that the casting may only fit atop the lattice 250, or become securely engaged by the lattice, in a single position. This engagement with the lattice can include multiple contact locations 248 having both vertical components that bear the weight of the castings and horizontal components that prevent the casting from moving or shifting laterally. Thus, once the casting 200 is settled into position atop the support fixture 240, it can be securely maintained in that position as the casting tray 220 is moved through one or more thermal treatment sections and subjected to a variety of applied loads by the impinging thermal fluids. For example, the casting support system 210 can facilitate the use of directed streams of high velocity thermal fluids during thermal treatments, including but not limited to jets of high pressure air or water during a quench cycle, that would tend to reposition or shift parts that are less securely supported on a casting tray.
Nevertheless, even though the support surface defined by the plurality of top edges 246 of the support plates 242 may be substantially complimentary with the underside of the casting 200, it need not be exactly conforming with the underside surface 206 along the length of the support plates 242. The support surface can instead include discrete contact locations 248 separated by gaps 247 where the top edges 246 are spaced from the underside surface 206 by a distance that is sufficient to allow thermal fluids to flow between the two surfaces. In one aspect the contact locations 248 between the lattice 250 and the underside 206 of the casting 200 can be judiciously located at predetermined key locations across the expanse of the underside surface that would otherwise be prone to sagging or distortion if not directly supported by the support fixture 240. In this way the casting 200 can be supported in space above the opening 226 using a reduced number of key contact locations 248, while leaving the remainder of the casting surfaces directly accessible by the thermal fluids.
Also shown in
The customizable fixture 240 of representative support system 210 can comprise four support plates 242 that are oriented vertically with lower portions 244 that extend across the tray opening 226 and top edges 246 that extend above the tray opening 226, and together form a lattice structure 250 in which the top edges 246 define the open support surface, or support profile, for the casting. In one aspect the support plates 242 can be substantially aligned with the major horizontal axes 212, 216 of the perimeter frame 230, with the lower edges 244 extending across the length or the width of the tray opening 226. In another aspects (not shown) the support plates can be aligned on the diagonal or at another angle relative the major horizontal axes of the perimeter frame 230. For the two support plates 252 of representative fixture 240 that are aligned parallel with the longitudinal axis 212 of the perimeter frame 230, the lower ends can terminate with notches 253 that engage the inner edges of the rectangular end bars 234 and crossbars 236, and may not extend across the centerlines of the crossbars 236 so as to not interfere with a fixture overlying the adjacent tray opening. For the two support plates 256 that are aligned parallel with the width axis 216 of the perimeter frame 230, the lower ends can extend outward past the side bars 232 and can include notches 257 formed into their lower edges that engage with mounting bars 238 that extend upward from the upper surfaces of the cylindrical side bars 232.
In one aspect the support plates 242 can intersect and connect with each other at predetermined locations defined by upwardly-opening half-slots formed into a lower pair of support plates 252 that mate with downwardly-opening half-slots formed into an upper pair support plates 256, as known in the art. In this way the support plates 242 of the support fixture 240 can become interlocked together to form the lattice 250 prior to attachment to the tray 220. Furthermore, and as described in more detail below, the positions of the interlocking support plates 252, 256 within the lattice 250 can be modified relative to each other and to the surrounding structure of the tray 220 in order to re-position the contact locations 248 of the top edge 246 underneath the portions of the casting that require the most support. In the illustrated embodiment this can be accomplished by adjusting the locations of the half-slots along the lengths of the support plates, and with the ends of the support plates being moved a corresponding distance along the end bars 234 or crossbars 236 or along the mounting bars 238 atop the side bars 232. Nevertheless, it will be appreciated that other connection methods or mechanisms for connecting the support plates 242 to each other and to the tray 220 are also possible and considered to fall within the scope of the present disclosure.
Also visible in
Castings 200 that are similar to the thin wall aluminum alloy HPDC shock tower 202 shown in
The support fixture 240 illustrated in
Additional detail and information regarding the casting support system disclosed above can be found in co-owned and co-pending U.S. Provisional Patent Application No. 62/222,407, filed Sep. 23, 2015, and entitled SYSTEM FOR SUPPORTING CASTINGS DURING THERMAL TREATMENT, which application is incorporated by reference in its entirely herein.
As described above in reference to
In one aspect of the present disclosure shown in the temperature vs. time graph of
It is also theorized that because the solution temperature of the silicon component is distinguishable from and less than the solution temperatures of the one or more metal alloying components, the solutionizing heat treatment of the aluminum alloy that ultimately results in the desired improvements in mechanical properties may not begin until the castings are heated to their alloying metal solution temperature. Thus, by recognizing and taking into consideration the differences between the silicon solution temperature and the alloying metal solution temperature, it is further contemplated that the time (t3) 436 spent by the castings at or above both the solution temperature 414 of the silicon component and the solution temperature 418 of the metal alloying component, prior to quenching, can be controlled to produce aluminum alloy castings having superior mechanical properties at reduced scrap rates, and with the castings having a substantial reduction in dimensional distortions that would otherwise result from the formation of enlarged bubbles of entrapped gases.
It will be appreciated that both the time duration (t1) 424 and the first heating rate 422 of the castings in the first heating stage 420 can vary substantially between different embodiments of the thermal treatment protocol 400. For reference purposes, the rise/run of the first heating rate 422 is defined as ° C./min, and can be applied as an instantaneous heating rate or as an average heating rate during a specified period of time, such as, for example, the entire first heating stage 420 or a merely a portion of the first heating stage 420. Factors that affect the duration (t1) and/or the first heating rate 422 can include the type and configuration of the furnace, the initial temperature 421 of the castings when the castings first enter the furnace, the thickness and/or the surface area exposure of the castings, and the like.
For instance, in some embodiments a casting may be quite thick, such as the casting for an engine block. It may also be preferable, moreover, for substantially all of the material of the thick casting to reach the first casting temperature 425 prior to entering the second heating stage 430. In such embodiments, the targeted heating profile may be achieved by heating the casting at a slower rate and then allowing the casting to soak at the first casting temperature 425 for a few minutes (e.g. 2-5 minutes or similar extended time period) toward the end of the first heating stage 420 to provide ample time for the heat to become evenly distributed throughout the casting. In other embodiments the casting may be a thin-walled structure with a greater proportion of exposed surface area that readily receives and distributes the applied heat to reach thermal equilibrium at the first casting temperature 425 in a much shorter period of time, in which case the thermal soaking period may be reduce or eliminated.
In other aspects, such as the embodiment shown in
In yet other aspects of the present disclosure, the first heating stage of the furnace can be maintained at a substantially constant first stage temperature that is greater than the first casting temperature 425, so as to maintain the flow of heat into the casting throughout the first heating stage 420.
In embodiments where first stage temperature is greater than the predetermined silicon solution temperature 414 at which the silicon component rapidly enters into solid metal solution, the movement of the castings through the furnace can be timed so that the castings reach the first casting temperature 425 and exit the first heating stage 420 prior to reaching the predetermined silicon solution temperature 414 or thermal equilibrium with the first stage temperature. In embodiments where the first stage temperature is less than the predetermined silicon solution temperature 414, the time duration (t1) 424 of the castings within the first heating stage 420 can be extended so that the castings approach thermal equilibrium with the first stage temperature simultaneous with reaching the first casting temperature 425.
Accordingly, in one aspect the first stage temperature of the first heating stage can be maintained within about 10° C., plus or minus, of the predetermined silicon solution temperature 414. In another aspect the first stage temperature of the first heating stage 420 can be maintained at a temperature that is greater than 10° C. above the predetermined silicon solution temperature 414, so as to provide an increase in the first heating rate 422 throughout the first heating stage 420 with a corresponding decrease in the time duration (t1) 424 of the first heating stage, and which can further include accurate control of the movement of the castings through the first heating stage 420 to ensure that the castings exit the first heating stage 420 prior to reaching the predetermined silicon solution temperature 414.
Upon reaching the first casting temperature 425 at the end of the first heating stage 420, the castings can then transition or move into the second heating stage 430 of the thermal treatment protocol 400 that generally comprises a second period of time (t2) 434 extending from the entrance of the castings into the second heating stage 430 until their exit and movement into the quench stage 440. Upon entry into the second heating stage 430, the castings are quickly heated from the first casting temperature 425 to a second casting temperature 435 that is greater than or substantially equal to the predetermined alloying metal solution temperature 418. The castings can then be maintained at the second casting temperature 435 for the remainder of the time period (t2) 434 of the second heating stage 430 in a substantially isothermal (i.e. constant temperature) portion 437 of the protocol 400. Depending on the time taken to heat the castings from the first casting temperature 425 to the second casting temperature 435 after entry into the second heating stage 430, the substantially isothermal portion 437 of the thermal treatment protocol 400 at the second casting temperature 435 can typically range from about 10 minutes to about 20 minutes. Nevertheless, substantially isothermal portions 437 that are less than 10 minutes in duration, such as between 5 minutes and 10 minutes in duration, are also possible and considered to fall within the scope of the present disclosure.
In one aspect the second casting temperature 435 can be between about 5° C. and 10° C. above the predetermined solution temperature 418 of the metal alloying component, in order to ensure that the metal alloying component in all portions of the casting reaches or exceeds the alloying metal solution temperature and enters into solid solution, but without excessively exceeding the alloying metal solution temperature in ways that could lead to detrimental side effects. In other aspects, such as when the alloying metal solution temperature is precisely known and the thermal treatment protocol 400 can be tightly controlled, the second casting temperature 435 can be 5° C. or less above the predetermined solution temperature 418 of the metal alloying component.
As illustrated in
In addition, the second heating stage 430 of the furnace can be maintained at a substantially constant second stage temperature that is greater than the first stage temperature, so as to maintain the flow of heat into the castings at least during the first portion of the second heating stage 430. In one aspect the additional heat input needed to quickly raise the temperature of the castings to the second casting temperature 435 can be provided by an additional heating apparatus, such as directed heaters or high flow hot air nozzles, that can direct additional heat onto the castings and provide a boost to the initial second heating rate 432. Moreover, the additional heating apparatus can be configured to raise the temperature of the castings to the second casting temperature 435 in a shortened period of time without raising the second stage temperature in the second heating stage portion of the furnace.
Once the castings reach the second casting temperature 435 that is associated with the substantially isothermal portion 437 of the protocol 400, the second stage temperature can prevent the flow of heat away from the castings for the remainder of the time period (t2) 434 of the second heating stage 430. In one aspect the second stage temperature can be substantially equal to the second casting temperature 435, while in other aspects the second stage temperature can be marginally higher than the second casting temperature 435 so that the temperature of the castings continues to rise slightly during the remainder of the second heater stage, but typically only a small amount as the time remaining in the second heating stage is relatively short. In one embodiment the second stage temperature can be less than about 10° C. above the predetermined alloying metal solution temperature 418 at which the at least one metal alloying component rapidly enters into solid metal solution.
In comparing the period of time (t3) 436 the castings spend at or above the predetermined solution temperature 418 of the metal alloying component with the overall time duration (t2) 434 of the second heating stage 30, as measured from entering the second heating stage 430 to entering the quench stage 440, the (t3)/(t2) timing ratio of the castings at the alloying metal solution temperature 418 can be 50% or greater. This timing ratio can also be known as the time-in-treatment ratio. As will be appreciated by those skilled in the art, the time-in-treatment ratio can be a good approximation of the actual percentage of time that the castings spend in the solutionizing heat treatment at or above the alloying metal solution temperature at which the metal alloying component rapidly enters into solid metal solution, in addition to being at or above the silicon solution temperature at which the silicon component rapidly enters into solid metal solution. It will also be appreciated that the time-in-treatment ratio provided by the present disclosure can be substantially increased over solution heat treatment methods for HPDC castings currently known and practiced in the art.
Indeed, depending on the temperature differentials between the predetermined silicon solution temperature 414 and the predetermined alloying metal solution temperature 418 and between the first casting temperature 425 and the predetermined silicon solution temperature 414, as well as the configuration of the furnace, it is contemplated that in some embodiments the (t3)/(t2) time-in-treatment ratio of the castings at or above the predetermined alloying metal solution temperature 418 can be greater than 60%, greater than 70%, or even 80% or greater. For example, if it has been determined that the (t2) value for a particular alloy is limited to 418 minutes in order to avoid the manifestation of blistering and/or dimensional distortion on a high percentage of the castings, a (t3)/(t2) time-in-treatment ratio of 75% can ensure that the castings are maintained at or above the predetermined alloying metal solution temperature for about 13.5 minutes. In this way the castings can obtain a substantial increase in the beneficial affects of an alloying metal solutionizing heat treatment while avoiding the harmful effects of the pore-based defects by limiting the time spent at or above the silicon solution temperature.
It will thus be appreciated that heating the castings in the first heating stage 420 to a first casting temperature 425 that is near to the predetermined silicon solution temperature 414, can be advantageous for both reducing the heating requirements in the second heating stage 430, and for reducing the time needed to reach the predetermined alloying metal solution temperature 418 as the castings are heated to the second casting temperature 435 in the second heating stage 430.
Upon reaching the end of the second heating stage 430, the castings can then transition or move into the quench stage 440 of the thermal treatment protocol 400 in which the castings are quickly cooled from the second casting temperature 435 to a quenched temperature 445 that is generally less than 250° C. but still well above ambient temperature. The quench stage 440 generally comprises a liquid spray cooling system, a forced air or gas cooling system, a liquid immersion cooling system, or combinations of the above. During the quench stage 440 the castings can be cooled at a cooling rate 442 for a time period (t4) 444 that generally ranges from one to about five minutes. After completion of the quench stage 440, the castings can be removed to ambience and allowed to cool and naturally age for a T4 temper, or to a separate temperature controlled chamber (not shown but known to one of skill in the art) for artificial aging at an elevated temperature for a predetermined period of time to achieve a T6 temper. As will be appreciated by one of skill in the art, other quenching and aging protocols are also possible and considered to fall within the scope of the present disclosure.
Additional detail and information regarding the thermal treatment protocol 400 disclosed in
Upon completion of the initial or first thermal treatment protocol, the one or more treated test castings 101 (as opposed to the untreated castings 100 prior to or during thermal treatment) can again be allowed to cool or rest for a period of time within a temperature controlled environment and to reach a state of thermal equilibrium at the predetermined measurement temperature. At this point the method can proceed with capturing a second digitized, three dimensional surface measurement of the test casting 101 to determine its post-treatment three dimensional shape, after which the post-treatment shape can be compared with the baseline shape to determine if the shape of the part changed during the thermal treatment protocol, and if so, at what locations and by how much. As shown in the side view of
A common indication of high amounts of dissolved gases and porosity internal to the casting are blisters on the exterior surfaces of a treated casting 101, and in one aspect the surface of the treated test casting proximate the dimensional distortions can be inspected to identify surface porosity related to an increased concentration of dissolved gases in the alloy material. It is possible, however, to have internal, localized regions of high gas content causing exterior dimensional distortions without significant accompanying surface blistering or defects. In this case the casting can also be sectioned proximate the dimensional distortion to identify internal porosity related to high gas content in the alloy material.
If it is determined that the dimensional distortions 182, 184 in the treated test casting 101 are the result of high gas content in the alloy material, in one embodiment the method can continue with the application of a second and different thermal treatment protocol that is intended to eliminate or substantially reduce the development of internal porosity-related distortions within other untreated test castings. For example, to verify that at least of portion of the source for the dimensional distortions is high gas content within the alloy material, the initial or proposed thermal treatment protocol for the untreated castings 100 can be altered by reducing the period of time during which the castings experience temperatures that are above the predetermined silicon solution temperature 414 of the alloy material, as described above in reference to
As shown in the temperature vs. time plot of
The process furnace 450 can include an internal barrier with a gate or intermediate door 464 that divides the interior of the insulated enclosure 454 into a first heating stage 420 and a second heating stage 430 that coincide with the first heating stage 420 and second heating stage 430 depicted in
In one aspect the temperature of the first heating stage 420 can be maintained at the first casting temperature 425 and the time duration (t1) 424 can be extended until thermal equilibrium is gradually established between castings 405 and the heated air in the first heating stage 420. The temperature of the second heating stage 430 can likewise be maintained at the second casting temperature 435, but with the additional heat input at the beginning of the second heating stage 430 to quickly bring the castings into thermal equilibrium between castings 405 and the heated air in the second heating stage 430.
Also visible in
Furthermore, it will be appreciated that the output of the heater assembly in the first heating cell of the second heating stage 430 may not be sufficient to raise the initial or second heating rate 432 to the desired value. In this case one or more additional heating apparatus 468, such as an additional heater or hot air nozzle, can be added to the affected heating cell to direct additional heat onto the castings 405 and provide a boost in the initial or second heating rate 432 that will raise the temperature of the castings to the second casting temperature 435 in a shortened period of time. For furnaces 450 having an adjustable intermediate door 464, empty support fixtures filled with insulating plugs 469 can also be provided at each additional optional location, so that the additional heating apparatus 468 can be repositionable along with the intermediate door 464.
The process furnace 470 schematically illustrated in
In this embodiment of the process furnace 470, however, the position of the intermediate door 484 along the length of the enclosure 454 can be fixed and the conveyor system can comprise conveyor chains 472, 473 (i.e. parallel synchronized pairs of chains) having independently controllable operating speeds. The two independently controllable conveyor chains 472, 473 can provide the user with the capability of independently configuring the time duration (t1) of the first heating stage and the time duration (t2) of the second heating stage, which in turn can allow for optimization of both the first heating rate 422 and the (t3)/(t2) time-in-treatment ratio in the second heating stage 430. In one aspect the two conveyor chains 472, 473 can meet together at the first transition zone 429 (i.e. the intermediate door 484), as illustrated in
The solution heat treating system 550 illustrated in the plan view of
Also shown in
With the batch-type heat treating furnaces 560 of the solution heat treating system 550 of
Despite the possible inefficiencies of batch-type heat treating resulting from the repeated heat cycling within the furnace chamber, one advantage provided by the heat treating furnaces 560 of
Additional detail and information regarding the thermal treatment systems disclosed above can also be found in aforementioned U.S. Provisional Patent Application No. 62/153,724, as referenced and incorporated above.
In applying the second and different thermal treatment protocol to the second test casting, the same support fixture and support profile can be used to carry the casting within the thermal treatment zones, so as to reduce the number of variables that could affect the results of the second test. Once the second thermal treatment protocol is complete, the second treated casting 101 can also be allowed to cool until a state of thermal equilibrium at the predetermined measurement temperature is reach, at which point another digitized, three dimensional surface measurement of the second casting 101 can be captured to determine its post-treatment three dimensional shape. This can be followed by a comparison of the post-treatment shape of the second casting with its baseline shape, similar to that shown in
It will be appreciated that a positive indication of high gas content within the HPDC castings, especially if the distortion and dissolved gases are localized within a specific region of the casting, can be useful information for the manufacturer or designer of the HPDC dies. With this information the die manufacturer may be able to redesign the die or HPDC process in such a way so as to reduce the amount of gases that are available for absorption by the molten casting material. For example, in one aspect the vents in the mold cavity could be modified or relocated to provide a better escape path for the gases and vapors that are present within the mold cavity when the hot melt is introduced at high pressure and velocity. In other aspects the gates for directing the molten metal into the mold cavity could also be modified or repositioned to better control the flow pattern as the casting material fills cavity and pushes the gases and vapors out through the vents.
With reference back to
The initial or first thermal treatment protocol can then be re-applied to the second casting supported on the second fixture so as to reduce the number of variables that could affect the results of the second test. Once the second run through the first thermal treatment protocol is complete, the second casting can also be allowed to cool until a state of thermal equilibrium at the predetermined measurement temperature is reach, at which point another digitized, three dimensional surface measurement of the treated second casting 101 can be captured to determine its post-treatment three dimensional shape. This can be followed by a comparison of the post-treatment shape of the second casting with its baseline shape, similar to that shown in
As discussed above, it is also possible for the dimensional distortions 182, 184 in the treated test casting 101 to be the result of an incomplete or improper application of thermal fluids to the casting within the thermal treatment zones, and particularly in a manner that creates large temperature gradients through the thickness or across the expanse of the alloy material resulting in dimensional distortions that remain set within the casting material after the thermal treatments are completed and the casting has returned to an ambient equilibrium temperature. Moreover, the improper application of thermal fluids is generally more of an issue during the quench stage 440 of the thermal treatment protocol 400 (
For example, in another aspect of the present disclosure shown in
The multi-stage quench system 600 also generally includes a pressurized liquid spray cooling system 630 and a bulk air cooling system 640. The liquid spray cooling system 630 can include a source of pressurized cooling liquid in fluid communication with a plurality of nozzles 632 with nozzle heads 634 through one or more manifolds 631. The nozzles 632 are configured to spray the cooling liquid 636 onto the hot casting 100 during one or more portions of the quench cycle to provide a liquid spray quench. The cooling liquid 636 can generally comprise water or a mixture of water and one or more additional liquid components, such as glycol. In addition, the nozzle heads 634 can be configured to provide the cooling liquid 636 in a variety states, from high pressure/high velocity streams with large drops to atomized mists formed from droplets having an average size of less than or about 100 μm. In another aspect, the temperature of the cooling liquid 636 prior to dispersal from the nozzles may be maintained at a predetermined temperature that has been optimized to provide the desired cooling affects.
The nozzles 632 and nozzle heads 634 of the liquid spray cooling system 630 can be configurable in both direction and flow so as to provide precision control over the application of cooling liquid 636 onto the hot casting 100 for extracting heat therefrom. For example, the configuration of individual nozzles 632 and nozzle heads 634 may be customizable, either manually or by programmable actuation, to match a particular casting part, so as to increase the amount of cooling liquid 636 that is applied to the thicker portions of the test casting relative to the amount of cooling liquid that is applied to the thin-wall portions of the casting. Furthermore, the cooling liquid can be simultaneously applied to all sides or exposed surfaces of the casting (i.e. front, back, sides, bottom, top, or internally). In this way the casting may be cooled in a substantially uniform manner throughout the liquid spray cooling portion(s) of the quenching cycle. Because the relative temperatures of the various portions of the casting can be maintained substantially equal throughout the quenching cycle, any thermally-induced internal stresses and the resulting dimension distortions of the casting can be substantially reduced.
The bulk air cooling system 640 can include one or more rotatable cooling fans 642 that are configured to provide a bulk flow of cooling air 644 that enters the quench chamber 626 through an entrance 624, passes across and around exterior surfaces of the hot casting 100 to remove heat from the casting, and then exits the chamber 626 through one or more exits 628 as an exhaust flow 648. In one aspect the temperature and flow rate of the bulk cooling air 644 can be controlled to provide the desired cooling characteristics. For instance, the motors driving the rotatable cooling fans 642 can be powered by variable frequency drives (VFDs) that can provide a continuously variable bulk flow of cooling air across a wide range of operating speeds or frequencies. The bulk air cooling system 640 and the chamber 626 may also be configured to ensure that the cooling air 644 passes over substantially all of the exposed exterior surfaces of the casting to cool the casting in a substantially uniform manner throughout the force air cooling portion(s) of the quenching cycle.
As understood by one of skill in the art, moreover, the configuration of the bulk air cooling system 640 depicted in
The multi-stage quench system 600 also generally includes a programmable controller 616, such as a computer or similar electronic processor-based device, that is configured to activate and deactivate the bulk air cooling system 40 and the pressurized liquid spray cooling system 630. Thus, the controller 616 can be used to adjust the cooling provided by the liquid spray cooling system 630 and the bulk air cooling system 640 to ensure that each type of casting 100 can experience a specific, pre-programmed quenching process. In one aspect the controller 616 can also be used to automatically adjust the positioning and flow of liquid through individual nozzles 32, as described above. Alternatively, the quench system 600 may utilize a basic timer system wherein a set defined time schedule is used for sequentially activating and deactivating each of the cooling systems 630, 640.
Also shown in
Once the hot casting 100 has been positioned or secured within the quench chamber 626, the bulk air cooling system 640 and the liquid spray cooling system 630 can be operated independently, or together, to rapidly quench the casting using a predetermined sequence of quenching stages or steps. For example, one exemplary embodiment of utilizing the multi-stage quench system 600 of the present disclosure is expressed below, as might be applied to an aluminum alloy casting. In particular, the temperature vs. time graph of a representative process 650 for quenching the aluminum alloy casting is provided in
Prior to entering the first stage (“Stage I”) 660 of the quenching process 650, the hot casting can be placed into the quench system at an initial temperature 662, such as an elevated post heat treatment temperature as the casting leaves a solution furnace. The bulk air cooling system 640 can then be activated to provide a Stage I air quench 664 that cools the casting from the initial temperature 662 to a first intermediate temperature 672. The Stage I air quench 664 takes place during a Stage I time period 666 that, in one embodiment, can last between about 5 seconds and about 20 seconds. In some aspects the Stage I cooling rate 668 can be substantially linear or constant (as also shown in
At the conclusion of the first stage 660 of the quenching process 600, the bulk air cooling system 640 can be deactivated and the liquid spray cooling system 630 activated to provide a second stage (“Stage II”) liquid (or liquid/air) spray quench 674 that further cools the casting from the first intermediate temperature 672 to a second intermediate temperature 682. The Stage II spray quench 674 can have a time period 676 that, in one embodiment, can last between about 5 seconds and about 20 seconds. In some aspects the Stage II cooling rate 678 can be substantially constant, while in other aspects the Stage II cooling rate 678 may be variable.
After the casting temperature has reached the second intermediate temperature 682, the liquid spray cooling system 630 can be deactivated and the bulk air cooling system 640 re-activated to provide a third stage (“Stage III”) air quench 684 that further cools the casting from the second intermediate temperature 682 to a final quench temperature 692. The Stage III spray quench 684 can have a time period 686 that, in one embodiment, lasts between about 5 seconds and about 10 seconds. In some aspects the Stage III cooling rate 688 can be substantially constant, while in other aspects the Stage III cooling rate 688 may be variable. When the Stage II cooling liquid is water, the Stage III air quench can also function to dry any residual moisture that remains on the casting after the Stage II spray quench 674. After reaching the final quench temperature 692, the casting can be allowed to gradually cool 144 to ambient temperature for natural aging, or may be transferred to a secondary furnace for artificial aging at an elevated temperature, and for an extended period of time, before being allowed to cool naturally.
As discussed above, each of the air quench stages 664, 684 and the spray quench stage 674 can be configured to cool the casting in a substantially uniform manner throughout the quench steps to reduce the thermally-induced stresses that may develop within the part. This feature of the disclosure can function to minimize or substantially reduce the thermally-induced dimensional distortions that may otherwise be generated during the quenching processes, resulting in fewer castings that are rejected for falling outside of dimensional tolerances.
In one embodiment the total time to perform the multi-stage quenching process 650 on a hot aluminum alloy casting, from the initial temperature 662 to the final quench temperature 692, can range from about 15 seconds to about 50 seconds. Although the multi-stage quenching process 650 can take longer than an immediate immersion quench in water or oil, as presently available in the art, the ability to variably control the cooling rate of the casting throughout the quenching process can result in a quenched casting with improved metallurgical properties and reduced dimensional distortions. In some aspects, moreover, it is contemplated that the multi-stage quenching process 650, when used to conclude a properly-optimized solution heat treatment process, can provide the resulting casting with such improved metallurgical properties that the additional step of artificially aging the casting at an elevated temperature in a secondary furnace may not be necessary to meet structural performance requirements.
It will be appreciated that the multi-stage quench system 600 and quenching process 1650 illustrated in
The multi-stage quench system 700 generally includes an elongated enclosure 202 that defines a quench chamber 206, with multiple castings (not shown) traveling through the chamber 706 at a substantially constant speed 701 from an entrance opening 704 at one end of the enclosure 702 to an exit opening 708 at the opposite end. The enclosure 702 can include a first section 710 having a bulk air cooling system 712 that provides a Stage I air quench 664 (
After passing through the first section 710, the castings can then enter a second section 720 having a liquid spray cooling system 722 that provides a Stage II spray quench 674 (
Upon reaching the end of the second section 720, the castings can then pass into a third section 730 having another bulk air cooling system 732 that provides the Stage III air quench 684 (
Also shown in
With continued reference back to
Additional detail and information regarding these multi-stage quench systems can be found in co-owned and co-pending U.S. patent application Ser. No. 14/855,498, filed Sep. 16, 2015, and entitled SYSTEM AND METHOD FOR QUENCHING CASTINGS, which application is incorporated by reference in its entirely herein.
Alternatively, in yet another aspect of the present disclosure shown in
The quench air system 800 can also include a plurality of nozzle baffles 840 that extend inward from sidewalls 824 of the quench housing to 820 to the inside of the outermost rollers 832 of a roller conveyor. The nozzle baffles 840 can operate to redirect those portions 892 of the cooling air 890 that flow upward along the sidewalls 824 of the quench housing 820 toward the center portion of the quench housing 820, thereby increasing the speed of the forced cooling air 890 as it flows upward through the casting tray 860. In one aspect the nozzle baffles 840 can include fixed upwardly and inwardly slopped portions 842 that curve aerodynamically into vertical lips 846 that extend upward and adjacent to the inner edges of the outermost rollers 842, without contacting the rollers, so as to maximize the increase the velocity of the cooling air 890 while minimizing pressure losses. However, other configurations and/or shapes for the nozzle baffles 840 are possible and considered to fall within the scope of the present disclosure.
Although not shown in the schematic side view of
Also illustrated in
Although not visible the drawing, in one aspect the width of the central baffles 850 may vary along the length of the vane-shaped structure (i.e. while moving perpendicular to the plane of the drawing) so as to define channels of varying size and shape that can be optimized to better define and shape the streams of cooling air 890. For example, in some aspects the profile of the central baffles 850 can be shaped to match large openings 882 formed through the castings 880 themselves (for example, empty cylinder bores or crank shaft bores), so that a high velocity stream of cooling air can be directed to flow upward through the interior of the castings in addition to the high velocity streams of cooling air flowing across the exterior surfaces of the castings 880. In this way a greater proportion of the cooling air provided by the forced air fans can be utilized to cool the castings, thereby increasing the effectiveness, efficiency and cooling rates of the quench system 800.
Both quench stations in the quench air system 900 can include nozzle baffles 940, 946 and movable central baffles 950, 956. The nozzle baffles 940, 946 can be fixed, and can serve to redirect those portions 992 of the cooling air 990 that flow downward along the sidewalls 924 toward the center portion 922 of the quench housing 920, thereby focusing and increasing the speed of the forced cooling air 990 as it flows downward through and around the castings that are supported on the casting trays. In this embodiment, however, the nozzle baffles 940, 946 can extend inward from the sidewalls 924 at locations above the roller conveyors 930, 935 of each quench station and by a distance 926 that allows a casting tray loaded with castings to roll in under the nozzle baffles, which in one aspect can include the lower vertical lips 944, 948 shown in the illustrated embodiment. In addition, since the nozzle baffles are located above the quench stations, the size and shape of the nozzle baffles 940, 946 is not constrained by the roller conveyers. This can allow the nozzle baffles to be configured or customized, if so desired, to more accurately conform to the footprint of the castings 980 that are loaded on their respective casting trays 960. As these flow areas will generally be much smaller than the total cross-sectional area of the quench closure 920, the nozzle baffles 940, 946 can provide a first redirection or concentration of the forced air flow and a corresponding first stage increase in flow velocity.
Similar to the embodiment of the quench air system described above, the movable central baffles 950, 956 that are positioned near or within the mouth of the nozzle baffles 940, 946 can provide a second and more localized redirection or concentration of the forced air flow and a corresponding second stage increase in flow velocity. The central baffles 950, 956 can also be provided with shaped profiles that can define and shape the streams of cooling air to correspond with openings and/or other structures formed into the castings below, and in this way can be used to tailor the cooling stream to provide improved cooling for specific castings. However, since the movable central baffles 950, 956 are also located above the quench stations and not constrained by the roller conveyers 930, 935, the number, size and shape of the central baffles 950, 956 can be substantially different than those movable baffle designs that are intermixed with the rollers (see, for example, the embodiment of
When the first casting tray 960 loaded with a first group of castings 980 is positioned within the lower quench station, the central baffles 950 that are associated with the first station can be moved or rotated to their active orientations (in the depicted case, a horizontal orientation) that redirects and concentrates the downwardly-flowing forced cooling air into narrow gaps or shaped channels 935 that correspond with openings or other structures formed into the castings 980 below. At the same time, the central baffles 956 that are associated with the second quench station (that is now upstream of the first quench station) can be moved to their vertical or inactive orientations so as to reduce any drag and pressure loses caused by the overlying structures.
When the first casting tray 960 is withdrawn from the lower quench station and the second casting tray loaded with a second group of castings is positioned within the upper quench station (not shown), it will be appreciated that the central baffles 950 that are associated with the first station can be moved to their vertical or inactive orientations so as to reduce the backpressure generated by the structures that are now downstream of the castings being quenched. At the same time, the central baffles 956 that are associated with the second quench station can be moved or rotated to their active orientations (e.g. a horizontal orientation) that redirects and concentrates the downwardly-flowing forced cooling air into narrow gaps or shaped channels 935 that correspond with the openings or other structures formed into the castings 986 immediately below.
Additional detail and information regarding these forced air quench can be found in co-owned and co-pending U.S. Provisional Patent Application No. 62/197,199, filed Jul. 27, 2015, and entitled SYSTEM AND METHOD FOR IMPROVING QUENCH AIR FLOW, which application is incorporated by reference in its entirely herein.
In yet another aspect of the present disclosure illustrated
In sum, the methods and systems of the present disclosure can be employed to improve the thermal treatment of castings, and in particular the thermal treatment of production HPDC castings, for enhanced metallurgical properties and reducing dimensional distortions. The methods and systems generally include the knowledgeable application of the customizable casting support system described above, in combination with thermal treatment systems that are capable of adjustably applying thermal treatment protocols to mitigate or avoid many of the problems associated with the high volume production of thin wall aluminum alloy castings that have been formed in an (HPDC) process
The invention has been described herein in terms of preferred embodiments and methodologies considered by the inventor to represent the best mode of carrying out the invention. It will be understood by the skilled artisan, however, that a wide range of additions, deletions, and modifications, both subtle and gross, may be made to the illustrated and exemplary embodiments without departing from the spirit and scope of the invention. These and other revisions might be made by those of skill in the art without departing from the spirit and scope of the invention that is constrained only by the following claims.
This application is a continuation of International Application No. PCT/US2016/058602, filed on Oct. 25, 2016; which application claims the benefit of U.S. Provisional Patent Application No. 62/251,139, filed on Nov. 5, 2015. Each application is incorporated by reference in its entirety herein and for all purposes.
Number | Date | Country | |
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62251139 | Nov 2015 | US |
Number | Date | Country | |
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Parent | PCT/US2016/058602 | Oct 2016 | US |
Child | 15956836 | US |