The present invention relates to a casting apparatus, such as a mold and a sprue bushing, used for die-cast casting or a similar casting and a method for manufacturing the casting apparatus. More specifically, the present invention relates to the casting apparatus that internally includes cooling flow passages for cooling the casting apparatus and the method for manufacturing the casting apparatus.
Conventionally, build-up welding has been performed to repair molds, and there has been proposed an improvement of the method (for example, Japanese Unexamined Patent Application Publication No. 2011-115807). In manufacturing the molds as well, to expand a freedom of design for forming a flow passage, the manufacturing method using the build-up welding has been proposed (for example, Japanese Unexamined Patent Application Publication No. 2004-34133, Japanese Unexamined Patent Application Publication No. H05-309468, and Japanese Unexamined Patent Application Publication No. 2005-52892). Meanwhile, a spread of water-soluble mold release agent for die-casting or a similar agent allows rapidly cooling the molds. While shortening of a manufacturing cycle is achieved, a problem of a heat check and a crack is likely to occur. Furthermore, it has been known as technical common knowledge that the welding repair is one cause of reduction in mold life (“Measures For Service Life Of Mold For Die-Casting”, written by Masahiko Hihara, published by NIKKAN KOGYO SHIMBUN, LTD., Feb. 28, 2003, p. 289). The introduction of a cooling flow passage has been proposed also for the casting apparatus other than the mold such as the sprue bushing (Japanese Unexamined Patent Application Publication No. 2003-10953).
However, while a welding process is suitable for manufacturing the cooling flow passage, which is required to feature air tightness, from the aspect of durability of the casting apparatus, sufficient examination has been required to the welding process.
One or more embodiments provide a casting apparatus manufactured using the welding process for manufacturing the cooling flow passages while minimizing deterioration of durability of the casting apparatus and a method for manufacturing the casting apparatus.
One or more embodiments of the present invention provides a casting apparatus for manufacturing cast products from molten metal. The casting apparatus includes a molten metal contacting surface and a cooling portion. The molten metal contacting surface is in contact with the molten metal. The cooling portion forms a cooling flow passage. The cooling flow passage is configured to cool the molten metal contacting surface. At least a part of an inner surface of the cooling flow passage is constituted of a welding portion formed by welding. The welding portion seals the cooling flow passage. The welding portion is constituted such that an exposure to the molten metal becomes equal to or less than a predetermined ratio with respect to an area of the welding portion constituting the inner surface of the cooling flow passage.
With the casting apparatus of one or more embodiments according to the present invention, at least a part of the inner surface of the cooling flow passage is constituted of the welding portion formed by welding. This allows minimizing excessive temperature rise by casting and also allows minimizing rapid temperature fall by cooling with a mold release agent. Meanwhile, the welding portion is constituted such that the exposure to the molten metal becomes equal to or less than the predetermined ratio with respect to the area of the welding portion constituting the inner surface of the cooling flow passage. This allows minimizing an influence of fatigue degradation caused by a temperature cycle by sufficient cooling. Consequently, the reduction in durability of the casting apparatus caused by the welding process can be minimized. The predetermined ratio can be set appropriately depending on the operating state and the design of the casting apparatus.
The following describes respective embodiments of the present invention in the following order. It will be understood that the scope of the present invention is not limited to the described embodiments, unless otherwise stated.
A. Constitution of Casting Apparatus (Mold) in First Embodiment:
B. Method for Using Mold in First Embodiment:
C. Method for Manufacturing Mold in First Embodiment:
D. Constitution of Casting Apparatus (Spool Bush) in Second Embodiment:
E. Method for Manufacturing Spool Bush in Second Embodiment:
F. Constitution of Casting Apparatus (Mold) in Third Embodiment:
G. Method for Manufacturing Mold in Third Embodiment:
H. Modification:
The insert die 110 includes a first part 111, a second part 112, and a bolt 113. The first part 111 has the product shape forming surface 110s. The second part 112 has an outer surface fitted to the depressed portion 130c of the movable-side main mold 130. The bolt 113 permanently fastens the first part 111 and the second part 112. In this embodiment, when viewed from the axial direction of the bolt 113, all the three product shape forming surfaces 110s, 120s, and 130s have a circular shape around its axial center. The product shape forming surfaces 110s, 120s, and 130s are also referred to as molten metal contacting surfaces.
The product shape forming surface 110s of the insert die 110 has protrusions 111p. The protrusion 111p is a shaping part disposed upon request of outer specification of cast products. Focusing on the shape of the protrusion 111p, the protrusion 111p has a property of likely to be a high temperature during a molten metal pouring process and likely to be rapidly cooled during cooling. This is because that while the protrusion 111p is surrounded by molten metal and cooling water, a heat conduction path to the movable-side main mold 130 is narrow.
The insert die 110 includes cooling water passages 114 (which corresponds to a cooling portion in the appended claims) to reduce the above-described temperature change. The cooling water passage 114 has an annular, circulating shape viewed from the axial direction of the bolt 113. The cooling water passage 114 communicates with a cooling water inlet and a cooling water discharge port (not illustrated). The cooling water passages 114 are formed by covering openings of the annular depressed portions, which are formed at the first part 111, with the second part 112. The cooling water passage 114 is sealed from the outside of the cooling water passage 114 with a weld bead 110b (also referred to as a welding portion or a weld-overlay portion), which joins the first part 111 and the second part 112.
The fixed-side main mold 120, the movable-side main mold 130, the first part 111, and the second part 112 are all made of an SKD 61 and/or other tool steels. The weld bead 110b is a part over which deposited metal with a composition similar to the SKD 61 is overlaid. This build-up welding is formed by TIG welding using a TIG welding rod (for example, DS-61G). The combination of a plurality of components forms the movable-side main mold 130 and the insert die 110, thus constituting one side of the mold 100.
The entire outer surface of the weld bead 110b is in contact with the inner surface of the depressed portion 130c of the movable-side main mold 130. Thus, the mold 100 is constituted such that the weld bead 110b is not to be exposed to the molten metal. Since the weld bead 110b is not exposed to the molten metal, this allows preventing a heat cycle caused by the contact of the weld bead 110b with the molten metal. Furthermore, the entire outer surface of the weld bead 110b is in contact with the movable-side main mold 130, this allows exchanging heat remarkably effective between the outer surface and the movable-side main mold 130. Accordingly, partial excessive temperature change only at the outer surface of the weld bead 110b can be minimized. This allows minimizing a heat check and a crack.
Step S11 performs a mold-setting-up process. The mold-setting-up process forms a mold with the fixed-side main mold 120 and the movable-side main mold 130 from which the cast product has been taken out and where the cooling has been completed (see
Step S12 performs the molten metal pouring process. The molten metal pouring process press-fits a high-temperature molten metal to the mold. As the molten metal, for example, an aluminum alloy is used. This heightens the temperatures of all the product shape forming surfaces 110s, 120s, and 130s. Meanwhile, the molten metal hardens and an aluminum die-cast product (not illustrated) is casted. After completion of solidification, the process proceeds to the next process.
Step S13 performs a mold opening process. The mold opening process moves the movable-side main mold 130 to separate the movable-side main mold 130 from the fixed-side main mold 120 to allow extraction of the aluminum die-cast product (not illustrated). Step S14 extracts the aluminum die-cast product. Then, the manufacturing process for aluminum die-cast products with the mold 100 is completed. The manufacturing process for aluminum die-cast products proceeds to the next process, which does not use the mold 100.
Step S15 applies a mold release agent to the insert die 110, the fixed-side main mold 120, and the movable-side main mold 130 with a spray device 190 (see
The water-soluble mold release agent for die-casting forms mold-releasing films over the product shape forming surfaces 110s, 120s, and 130s. Meanwhile, evaporation of the water vapor allows the product shape forming surfaces 110s, 120s, and 130s to be rapidly cooled. This allows achieving the short cycle time of the casting process.
The rapid cooling of the product shape forming surfaces 110s, 120s, and 130s increases the problem of thermal fatigue, causing the heat check and the crack. Specifically, according to the knowledge of the inventor of this application, in a process where the product shape forming surfaces 110s, 120s, and 130s whose temperatures become high by the molten metal pouring process are rapidly cooled and contracted by the evaporation of the water vapor of the water-soluble mold release agent for die-casting, the heat check and the crack occur. This is because that the rapid contraction of the surface generates a thermal expansion difference between the surface part and the inner part, resulting in a strain.
In this embodiment, focusing on its shape, especially the protrusion 111p provided with the product shape forming surface 110s, has a property likely to be a high temperature during the molten metal pouring process. This is because that while the protrusion 111p is surrounded by the molten metal, the heat conduction path to the movable-side main mold 130 is narrow. However, in this embodiment, since the cooling water passages 114 are formed at the inside of the protrusions 111p, this allows minimizing the excessively high temperature of the protrusions 111p. Furthermore, while the process continues from the molten metal pouring process (Step S12) to the mold opening process (Step S13) and then proceeds to the application of the mold release agent (Step S15), the protrusion 111p can also be cooled with the cooling water passage 114. This allows effectively minimizing the heat check and the crack, which are caused by the cooling by the application of the mold release agent.
In this embodiment, the cooling water passages 114 are sealed by the weld beads 110b. With general technical common knowledge, it is considered that a mold life of a part of a die-casting mold where the welding repair has been performed is remarkably reduced compared with a non-welded portion (for example, Measures For Service Life Of Mold For Die-Casting, written by Masahiko Hihara, NIKKAN KOGYO SHIMBUN, LTD.). However, in this embodiment, it is less likely that the weld bead 110b causes the reduction in mold life at least due to the following reasons. The other reasons will be described later.
(1) Since the weld bead 110b seals the cooling water passage 114, the weld bead 110b is not in an excessively high temperature state.
(2) The weld bead 110b does not form the product shape forming surface 110s (not exposed to the enclosed space (see
(3) The weld bead 110b is in contact with the movable-side main mold 130. Accordingly, the weld bead 110b and the movable-side main mold 130 do not form a thermal boundary and do not generate excessively large heat gradient.
Accordingly, the mold 100 having the constitution of the first embodiment uses the welding process for manufacturing a cooling flow passage 140 while minimizing the deterioration of durability of the mold 100. This achieves the appropriate cooling flow passage, ensuring achieving the mold 100 having long life.
On the outer periphery of the first part 111, depressed portions 111w, which have a depressed shape for build-up welding, are formed. On the outer periphery of the second part 112, depressed portions 112w, which have a depressed shape for build-up welding, are formed.
Step S22 assembles the respective components. Specifically, the first part 111 and the second part 112, which constitute the insert die 110, are combined. The combined first part 111 and second part 112 are fastened by the bolt 113. This forms the depressed portions 111w and 112w (see
Step S23 performs the welding process. As described above, the welding process is performed by forming the weld bead 110b (see
Note that the TIG welding rod (for example, the DS-61G) forms the weld-overlay portion by the deposited metal with the composition similar to the SKD 61, and different from the welding repair, the first part 111 and the second part 112 are in the state of before quenching. Accordingly, the weld bead 110b forms the gradient metal having extremely smooth gradient by including a heating process. Accordingly, the first part 111 and the second part 112 are combined and fastened by the bolt 113, thus manufacturing a welded half-finished product of the insert die 110.
Step S24 performs the heat treatment (the quenching) on the half-finished product of the insert die 110. By this process, the insert die 110 has sufficient toughness and rigidity. In this respect, the first part 111, the second part 112, and the weld bead 110b before quenching are all integratedly quenched. Therefore, the weld bead 110b has a physical property significantly similar to the first part 111 and the second part 112. Accordingly, a physical property boundary hardly occurs between the weld beads 110b and the first part 111 and the second part 112 as the base material, ensuring effectively minimizing the thermal fatigue generated caused by the boundary.
Step S25 performs a finishing process. The finishing process includes the machining process to form the outer shape of the weld bead 110b into a shape so as to fit the depressed portion 130c of the movable-side main mold 130. Furthermore, the finishing process includes the overall machining process of the outer surface and the surface treatment to achieve an appropriate fitting state between the insert die 110 on which thermal distortion is generated and the movable-side main mold 130. Furthermore, the finishing process includes the machining process and the surface treatment to achieve the appropriate fitting state between the fixed-side main mold 120, the movable-side main mold 130, and the insert die 110.
Step S26 inspects the mold 100. This inspection includes a pressure resistance inspection, an X-ray inspection, or a similar inspection on the cooling water passage 114. These processes allow manufacturing the mold 100 having the constitution of the first embodiment.
This manufacturing process starts manufacturing the respective components of all the first part 111 and the second part 112, which constitute the insert die 110, from the process of the machining process on the materials, which is the SKD 61, before quenching, and after welding and joining the first part 111 and the second part 112, the first part 111 and the second part 112 are integratedly quenched. Furthermore, the welding process forms the weld-overlay portion with the deposited metal with the composition similar to the SKD 61. Accordingly, the physical property boundary hardly occurs between the weld beads 110b and the first part 111 and the second part 112 as the base material. As a result, the thermal fatigue generated caused by the boundary can be effectively minimized.
The spool bush 200 includes insertion liners 210, a bush body 220, outer liners 230, and a bolt 213. On the inner surfaces of the insertion liners 210, plunger holes 200h are formed. Through the plunger hole 200h, a plunger (not illustrated), which pushes the molten metal, passes. The insertion liner 210 is a replacement component. The inner surface of the plunger hole 200h is also referred to as the molten metal contacting surface.
The spool bush 200 is constituted as follows. The bolt 213 fastens the insertion liner 210 and the bush body 220. The outer liner 230 and the bush body 220 are permanently fastened with two weld beads 200b1 and 200b2 (also referred to as welding portions). The two weld beads 200b1 and 200b2 are each formed into a ring shape around the central axis of the spool bush 200.
The spool bush 200 includes cooling water passages 224 (which corresponds to the cooling portion in the appended claims). The cooling water passage 224 is formed of the inner surface of the outer liner 230 and a cooling groove 220g (see
The spool bush 200 is constituted such that the two weld beads 200b1 and 200b2 are not exposed to the molten metal during the operation. Thus, the two weld beads 200b1 and 200b2 are not exposed to the molten metal. This allows preventing a heat cycle, which is caused by the two weld beads 200b1 and 200b2 in contact with the molten metal.
On the inner periphery at the upper end and on the outer periphery at the lower end of the outer liner 230, a depressed portion 230w1 and a depressed portion 230w2, which have a depressed shape for build-up welding, are formed, respectively. On the outer periphery at the upper end and on the inner periphery at the lower end of the bush body 220, a depressed portion 220w1 and a depressed portion 220w2, which have a depressed shape for build-up welding, are formed, respectively (see
Step S22a temporarily assembles the respective components 220 and 230. Specifically, Step S22a combines the bush body 220 and the outer liners 230. In this respect, the depressed portions 220w1 and 230w1 to form the weld beads 200b1 (also referred to as the welding portions or the weld-overlay portions) are formed across the upper ends of the bush body 220 and the outer liners 230. The depressed portions 220w1 and 230w1 have a semicircular cross section. Furthermore, the depressed portions 220w2 and 230w2 to form the weld beads 200b2 are formed across the lower portion of the bush body 220 and the lower end of the outer liner 230. The depressed portions 220w2 and 230w2 have a semicircular cross section.
Step S23a performs the heat treatment (the quenching) on the respective components 220 and 230. This embodiment performs the heat treatment before the welding process in a state where the respective components 220 and 230 are disassembled. This is because that, regarding the shapes of the respective components 220 and 230, performing the heat treatment with the respective components 220 and 230 combined results in excessive internal stress, which is generated by the heat treatment.
Step S24a performs the welding process. Note that a finish machining process is performed before the welding process to assemble the respective components 220 and 230. This does not cause excessive internal stress after the heat treatment (in the form of a product). As described above, the welding process is performed by forming the weld beads 200b1 and 200b2 (see
Similar to the first embodiment, Step S25 performs the finishing process. The finishing process includes the machining process. The machining process forms the inner surface shape of the bush body 220 into a shape so as to fit the outer surface shape of the insertion liner 210, which is the replacement component. Similar to the first embodiment, Step S26 inspects the mold 100. Step S27 inserts the insertion liner 210 to the inside of the bush body 220, and the bolt 213 fastens both.
This manufacturing process forms the weld-overlay portions at all the respective components of the bush body 220 and the outer liner 230 with the deposited metal with the composition similar to the SKD 61. This ensures effectively minimizing the thermal fatigue.
The die-cast-casting-machine use spool bush 200 of the second embodiment uses the cooling water passages 224 to quickly solidify the molten metal, thus ensuring shortening the cycle time for casting. Furthermore, without the use of an O-ring or a similar component, the weld beads 200b1 and 200b2 where thermal fatigue is effectively minimized can constitute the cooling water passages 224. This allows enhancing the durability of the spool bush 200.
The cooling flow passage 320 is sealed by weld beads 300b1 and 300b2 at both ends. This forms columnar flow passages 320c1 and 300c2 at respective both ends of the cooling flow passage 320. The one end of the columnar flow passage 320c1 is sealed by the weld bead 300b1 and the other end is coupled to the circulation path. On the other hand, the one end of a columnar flow passage 320c2 is sealed by the weld bead 300b2 and the other end is coupled to the circulation path.
The weld beads 300b1 and 300b2 seal the one ends of both the columnar flow passages 320c1 and 300c2. Therefore, according to the usual viewpoint of hydromechanics, this structure forms a stagnation; therefore, cooling cannot be expected. However, according to analysis of the inventor of this application, the following has been found. Since the cooling water spouts and flows in at constant cycles by evaporation (in another technical field, this has been known as a so-called pop pop boat principle), this structure features high cooling capacity contrary to common sense.
Step S31 performs a drilling process (see
The drilling process includes a boring process and a rounding process. The boring process forms the holes 310 and 330 with a drill for boring (not illustrated). The rounding process rounds most depressed portions 310c and 330c (see
Step S32 performs a depressed portion forming process. The depressed portion forming process forms depressed portions 300w1 and 300w2 for build-up welding at both the end portions of the through-hole 320. The depressed portions 300w1 and 300w2 (see
According to the analysis of the inventor of this application, the larger the diameter D is, the larger the pressure resistance of the cooling flow passage while reduction in durability caused by welding becomes remarkable. Contrary, the smaller the diameter D is, the lower the pressure resistance of the cooling flow passage while the reduction in the durability caused by welding becomes small. Therefore, the diameters D of the weld beads 300b1 and 300b2 are the most preferable to be 1.5 times to twice the hole diameter viewed from the axial directions of the columnar flow passages 320c1 and 300c2, and are also preferable to be 1 time to 2.5 times of the hole diameter.
Note that the embodiment can be achieved even outside the range. From the aspect of durability, the weld beads 300b1 and 300b2 can achieve sufficient cooling as long as the exposure to the molten metal is constituted so as to be equal to or less than a predetermined ratio with respect to areas of the weld beads 300b1 and 300b2, which constitute the inner surfaces of the columnar flow passages 320c1 and 300c2. The predetermined ratio can be determined according to the operating form (the temperature of molten metal and the shape of the mold).
Step S33 performs the welding process. As described above, the welding process is performed by forming the weld beads 300b1 and 300b2 by the TIG welding using the TIG welding rod (for example, the DS-61G). The weld beads 300b1 and 300b2 are appropriately melted into the mold base metal 350, thus constituting a gradient metal. Thus, the half-finished product of the mold 300 is manufactured.
Step S34 performs the heat treatment (the quenching) of the half-finished product of the mold 300. With this embodiment as well, a physical property boundary hardly occurs between the weld beads 300b1 and 300b2 and the mold base metal 350, ensuring effectively minimizing the thermal fatigue, which is generated caused by the boundary.
Step S35 performs the finishing process. Step S36 inspects the mold 300. This inspection includes the pressure resistance inspection, the X-ray inspection, or a similar inspection on the cooling flow passages 310, 320, and 330. These processes can manufacture the mold 300 having the constitution of the third embodiment.
According to this manufacturing process, similar to the first embodiment and the second embodiment, the physical property boundary hardly occurs between the weld beads 300b1 and 300b2 and the mold base metal 350. Furthermore, since the cooling water spouts and flows in at constant cycles in the columnar flow passages 320c1 and 300c2 by evaporation, the weld beads 300b1 and 300b2 can be effectively cooled. Additionally, it is constituted such that the exposure of the weld beads 300b1 and 300b2 to the molten metal becomes equal to or less than the predetermined ratio with respect to the areas of the weld beads 300b1 and 300b2, which constitute the inner surfaces of the columnar flow passages 320c1 and 300c2, to ensure sufficiently cooling. As a result, the thermal fatigue generated caused by the boundary with the weld beads 300b1 and 300b2 can be effectively minimized.
In the above-described embodiment, this build-up welding is formed by the TIG welding using the TIG welding rod; however, another welding method may be employed. Note that since the TIG welding can obtain beautiful, high-quality weld beads (weld-overlay portions) and therefore is preferable in terms of allowing application to welding of various metals.
The casting apparatus may be constituted as follows. The casting apparatus has a plurality of components including a welding component having the welding portion. With the plurality of components assembled, the welding portion is constituted not to be exposed to the molten metal.
The casting apparatus may be constituted as follows. The casting apparatus is a mold. The molten metal contacting surface constitutes a part of the mold as a product shape forming surface. The product shape forming surface forms a shape of the cast product set in advance. An outer surface of the welding portion is constituted so as not to be exposed to the molten metal by contact with any of outer surfaces of the plurality of components.
The casting apparatus may be constituted as follows. The cooling portion is manufactured by welding a material before quenching and subsequently quenching the material.
The casting apparatus may be constituted as follows. The casting apparatus is a mold. The cooling flow passage includes a columnar flow passage. One end of the columnar flow passage is sealed by the welding portion. Another end of the columnar flow passage communicates with a circulation path. The circulation path causes a cooling medium to circulate. The welding portion has a diameter 1.5 times to 2.5 times of a diameter of the columnar flow passage viewed from an axial direction of the columnar flow passage such that the diameter becomes equal to or less than the predetermined ratio.
The casting apparatus may be constituted as follows. A length of the columnar flow passage from the one end to the other end is longer than the diameter of the columnar flow passage.
The casting apparatus may be constituted as follows. The casting apparatus is a sprue bushing. The molten metal contacting surface constitutes a path to cause the molten metal to pass through to supply the molten metal to the mold.
The casting apparatus may be constituted as follows. The columnar flow passage is a mold whose length from the one end to the other end is longer than the diameter of the columnar flow passage.
While one or more embodiments of the present invention seals the cooling flow passage by the welding process, the reduction in durability of the casting apparatus caused by the welding process can be minimized.
Number | Date | Country | Kind |
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2014-210324 | Oct 2014 | JP | national |
This application is a continuation application of U.S. patent application Ser. No. 14/854,438 filed on Sep. 15, 2015, which claims priority from Japanese Patent Application No. 2014-210324 filed with the Japan Patent Office on Oct. 14, 2014, the entire contents of which are i-s-hereby incorporated by reference.
Number | Date | Country |
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H08-108259 | Apr 1996 | JP |
H09-277009 | Oct 1997 | JP |
2006-326635 | Dec 2006 | JP |
Entry |
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Office Action issued in Japanese Patent Application No. 2014-210324, dated Aug. 7, 2018, with English Translation (11 Pages). |
Number | Date | Country | |
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20190060981 A1 | Feb 2019 | US |
Number | Date | Country | |
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Parent | 14854438 | Sep 2015 | US |
Child | 16171716 | US |