JP2018122327A - Die-cast chill block - Google Patents

Abstract

The present invention provides a die-cast chill block that has an extremely simple structure and can be easily provided, and that solidified metal solidified in a gas vent passage can be reliably taken out particularly from a fixed chill block. With the goal. SOLUTION: In a chill block A provided with a wave-shaped gas vent passage 3 continuous on opposite surfaces of a fixed chill block 1 and a movable chill block 2, the fixed chill block 1 is solidified at least in the gas vent passage 3. The extrusion pin 4 for extruding the solidified metal thus extruded is provided so as to be able to protrude. Moreover, the trapezoidal base part 5 which made the convex part 51 contact | abutted to a part of front-end | tip of the said extrusion pin 4 protrude in the center should just be provided in the surface of the movable chill block 2, and the extrusion pin 4 is provided. It is preferable that the elastic body 6 to be extruded by the elastic force is disposed in the fixed chill block 1. [Selection] Figure 1

Description

  The present invention relates to a die-cast chill block in which gas generated when molten metal enters a cavity can be efficiently discharged to the outside, and in particular, a die in which solidified metal solidified in a gas vent passage is reliably taken out. It relates to a chill block for casting.

  In general, when die casting is performed, defects such as pinholes occur when high-temperature and high-pressure gas generated by air or mold release agent left inside the mold is caught in the melt. When a cast product was machined, a pinhole or the like was likely to occur on the cut surface. A chill vent is used to overcome these drawbacks. This chill vent communicates with the cavity of the mold, and during molding, air and gas in the cavity are discharged outside the mold through the chill vent, and molten metal such as aluminum flowing into the cavity flows out of the mold. Before melting, a molten metal such as aluminum is solidified in the chill vent. As a result, the air and gas are almost completely extracted from the cast product, and a high-quality cast product free from pinholes is obtained.

  The conventional chill vent is a structure in which a wave-shaped gas vent passage continuous to the opposing surface of the chill block composed of a fixed chill block and a movable chill block is provided, and after the melt flowing into the gas vent passage is solidified, This solidified metal is taken out together with the casting solidified in the cavity. Since the solidified metal at this time is formed integrally with the cast product, if there is a mechanism for taking out the cast product, it is common not to provide a take-out mechanism dedicated to the chill vent.

  However, the solidified metal that has flowed into the degassing passage and the molten metal has solidified is easily broken when the solidified metal is taken out because the gap in the degassing passage is narrow, and part of it remains on the chill block side. There was a case. For this reason, there are JP-A-2000-301313 and JP-A-2006-239721 as proposals for reliably taking out the solidified metal.

  Japanese Patent Application Laid-Open No. 2000-301313 increases the strength to make a part of the solidified metal thick and difficult to break so that no part of the solidified metal remains on the chill block side when the cast product is taken out. The whole can be taken out from the chill block side. In this configuration, a notch is provided in a zigzag shape between the corrugated opposing walls formed of a plurality of convex strips provided on the opposing surfaces of the chill block, and at least the top of the convex strip of the corrugated opposing wall A notch is provided in a part, and the notch is formed in at least one of a fixed chill block or a movable chill block. The purpose of this is to ensure that the molding material (solidified metal) that has flowed into the gas vent passage can be reliably taken out of the mold when the cast product is taken out, and that the chill block can be easily processed. is there.

  However, since JP 2000-301313 thickens a part of the solidified metal, the strength to prevent breakage is increased. However, when the mold is opened after casting, the solidified metal is likely to stick to the chill block side due to solidification shrinkage. The current situation is that partial breakage of the zigzag solidified metal is still likely to occur. As a result, there is a fear that the solidified metal cannot be smoothly taken out of the mold. At this time, if the gap between the corrugated opposing walls is increased, the zigzag-shaped solidified metal will not be broken, but hot water spraying is likely to occur and defective products are likely to occur. For this reason, the present condition is that a clearance cannot be enlarged more than fixed.

  On the other hand, in Japanese Patent Application Laid-Open No. 2006-239721, in a chill block having a gas vent passage communicating with a mold cavity, a mold release means for extruding solidified metal solidified in the gas vent passage is solidified in the cavity. It is provided in both the fixed chill block and the movable chill block in a state independent of the product release mechanism. The mold release means includes an ejector plate, an ejector pin and a return pin fixed to the ejector plate, and a coil spring that urges the ejector plate in the pushing direction. In addition, the purpose is to allow the chill vent to be arranged regardless of the position of the mold release mechanism for castings, increasing the freedom of mold design, and making it easy to move the chill vent or newly install a chill vent in an existing mold. It is intended to be able to cope with.

  However, if Japanese Patent Application Laid-Open No. 2006-239721 is provided with a releasing means having the above-described configuration, it is necessary to provide a space for storing an ejector plate and a coil spring. Thus, the chill block cannot be made compact. Further, the solidified metal solidified in the gas vent passage is taken out by the ejector pins extruded from a plurality of locations. At this time, even if one of the plurality of ejector pins malfunctions, the take-out operation becomes difficult. There were problems such as becoming.

  Japanese Patent Laid-Open No. 7-116807 is provided with an extrusion bar interlocked with the casting product take-out device so that the solidified metal can be taken out from the chill block side. This is because the solidified metal is taken out from the chill block side. However, it is not a purposeful proposal. For this reason, there is no description of the action and structure of the extrusion rod, and it only describes that it is interlocked with a known casting product take-out device (not shown).

Japanese Patent Application No. 2000-301313 JP 2006-239721 A Japanese Patent Laid-Open No. 7-116807

  The present invention has an extremely simple structure and can easily provide a solidified metal take-out mechanism, and a die-cast chill block in which the solidified metal solidified in the gas vent passage is reliably taken out from a fixed chill block. The purpose is to provide.

  The present invention has been made in view of the above situation, that is, in a chill block provided with a wave-shaped gas vent passage continuous on the opposed surfaces of a fixed chill block and a movable chill block, at least the fixed chill block, The structure is provided with an extrusion pin for allowing the solidified metal solidified in the degassing passage to be extruded. Further, it is sufficient that a trapezoidal base portion having a convex portion that contacts a part of the tip of the extrusion pin is provided on the surface of the movable chill block, and the extrusion pin is extruded by an elastic force. It is preferable that the elastic body to be disposed is disposed in the fixed chill block. Furthermore, it is preferable to provide a tapered hole having an inclination angle larger than the inclination angle of the base portion at the outer edge of the hole for the push pin drilled in the fixed chill block. On the other hand, without providing an extrusion pin, a trapezoidal base part is provided on the surface of the movable chill block, and a tapered concave part having an inclination angle larger than the inclination angle of the base part and facing the base part, It is good also as a structure provided in the fixed chill block.

  In the chill block (A) having a wave-shaped gas vent passage (3) continuous on the opposed surfaces of the fixed chill block (1) and the movable chill block (2) as in claim 1, the fixed chill block ( 1) At least, by providing an extruding pin (4) for extruding the solidified metal solidified in the gas vent passage (3) so as to protrude, the solidified metal is fixed to the fixed chill block (1) of the chill block (A). ) From the side, especially solidified metal from the fixed chill block (1), so that the casting operation is hardly stopped and a high-quality cast product can be obtained efficiently. It becomes. Further, since the take-out mechanism is extremely simple, the take-out mechanism can be installed in a short time and at a low cost, and a small space can be used. Further, the solidified metal extrusion mechanism can be operated without any concern even if it is hardly maintained.

  A trapezoidal base part (5) is provided on the surface of the movable chill block (2), with the convex part (51) contacting the part of the tip of the push pin (4) projecting in the center as in claim 2. As a result, the molten metal flows in with the extrusion pin (4) recessed by the height of the convex portion (51), and when the mold is opened after solidification, the extrusion pin (4) is returned to its original position. The solidified metal can be extruded while being pushed back, so that the solidified metal can be reliably taken out.

  By disposing the elastic body (6) for extruding the extrusion pin (4) by elastic force as shown in claim 3 in the fixed chill block (1), the structure is simple and the number of parts is extremely high. It can be reduced. In other words, a hole (11) for sliding the push pin (4) and a storage hole (12) that can store the elastic body (6) are formed in the fixed chill block (1), and the elastic body (6). It is only necessary to provide a lid (7) so that it does not come out, and since there is no need to provide a separate component storage space as in the conventional product, it can be used with existing chill blocks (A), and the chill block (A) in use Even if it exists, it becomes possible to add the taking-out mechanism of the present invention.

  A tapered hole (13) having an inclination angle larger than the inclination angle of the base portion (5) is provided on the outer edge of the hole (11) drilled in the fixed chill block (1). As a result, the solidified metal easily adheres to the movable chill block (2) due to solidification and shrinkage, and the solidified metal is more easily peeled off from the fixed chill block (1).

  In the chill block (A) having a wave-shaped gas vent passage (3) continuous on the opposed surfaces of the fixed chill block (1) and the movable chill block (2) as in claim 5, the movable chill block ( In 2), a trapezoidal base part (5) is provided on the surface, is opposed to the base part (5), and has a tapered concave part having an inclination angle larger than the inclination angle of the base part (5) ( 8) is provided on the fixed chill block (1), so that it has an extremely simple structure and does not require a component storage space, and is solidified and contracted so that the solidified metal can easily stick to the movable chill block (2). The chill block (1) is hardly solidified metal. For this reason, the solidified metal is reliably taken out from the chill block (A), the casting operation is hardly stopped, and a high-quality cast product can be obtained efficiently. In addition, since the existing chill block (A) can be easily processed and handled, even the chill block (A) in use can be added with the mechanism of the present invention at a very low cost and in a short period of time. It becomes.

It is explanatory drawing which shows the principal part of embodiment of this invention. It is explanatory drawing which shows the principal part of each surface of the fixed side of a chill block of this embodiment, and a movable side. It is explanatory drawing which shows the extrusion part of this embodiment. It is explanatory drawing which shows the effect | action of the extrusion part of this embodiment. It is explanatory drawing which shows the principal part of each surface of the fixed side of a chill block of another embodiment, and a movable side. It is explanatory drawing which shows the extrusion part of another embodiment. It is explanatory drawing which shows the effect | action of the extrusion part of another embodiment.

  FIG. 1 is a view showing a main part of an embodiment of the present invention, FIG. 2 (a) shows a part of the surface of the fixed chill block, and FIG. 2 (b) shows a part of the surface of the movable chill block. FIG. (1) is a fixed chill block made of tool steel such as SKD61 for die casting. The fixed chill block (1) has a hole (11) through which an extrusion pin (4) to be described later slides. Further, a hole through which the flange (41) of the push pin (4) slides is formed in the middle, and a storage hole (12) into which an elastic body (6) described later can be mounted is further continuously formed. [See FIG. 2 (a)]. A tapered hole (13) is formed on the outer edge of the hole (11) so as to expand outward (expand downward in FIG. 3). The spreading angle of the tapered hole (13) is preferably about 30 degrees, for example. The tapered hole (13) is not always necessary. (2) is a movable chill block made of tool steel such as SKD61. (A) is a chill block composed of a fixed chill block (1) and a movable chill block (2).

  (3) is a wave-shaped gas vent passage continuing to the opposed surfaces of the fixed chill block (1) and the movable chill block (2), and the gas vent passage (3) communicates with the cavity. (4) is an extruding pin for extruding the solidified metal solidified in the gas vent passage (3), and the extruding pin (4) is slidably inserted into the hole (11). As shown in FIG. 3, a flange portion (41) is attached to the end portion of the extrusion pin (4). This extrusion pin (4) may be one, but may be provided more than that. Further, the position where the push pin (4) is provided is preferably on the inlet side of the gas vent passage (3) as shown in FIG.

  (5) is a trapezoidal base part in which a columnar or prismatic convex part (51) contacting a part of the tip of the extrusion pin (4) is projected in the center, and the base part (5) is a figure. As shown to 2 (b), it is provided in the surface of the movable chill block (2). Further, an angle smaller than the spread angle of the tapered hole (13) formed at the outer edge of the hole (11), for example, an angle of about 10 degrees is attached to the base part (5) as shown in FIG. At this time, by setting the taper angle of the base part (5) to be smaller than the taper hole (13), the solidified metal adheres to the surface of the movable chill block (2) provided with the base part (5). It becomes easy to adhere to the fixed chill block (1).

  (6) is an elastic body for urging and extruding the push pin (4) with an elastic force. The elastic body (6) includes a spring material such as a coil spring, rubber, and a synthetic material having elastic force. Use resin material. In addition, as a structure for extruding the extrusion pin (4), a structure using hydraulic pressure, air pressure, or the like may be used in addition to the above. (7) is a lid for accommodating the elastic body (6) inside the fixed chill block (1) so that the extrusion pin (4) is pushed out. The lid (7) includes an elastic body ( 6) A hole and a through hole for accommodating the hole are formed. Moreover, as a method of attaching the lid (7) to the fixed chill block (1), an attaching screw may be used, a screw may be provided and screwed, or an adhesive may be used. When two or more extruding pins (4) are provided, the number of holes (11), tapered holes (13), base (5), elastic body (6), lid (7), etc. also corresponds to the number. Shall.

  5 and 6 are diagrams showing another embodiment of the present invention. Compared with the embodiment, there is no push pin (4), and a convex part (51) is provided at the tip of the base part (5). The point is that it is flat without protruding, and the others are substantially the same. The different parts will be described in detail. First, the fixed chill block (1) is not provided with a hole (11) and a storage hole (12), and the tapered holes shown in FIGS. 5 (a) and 6 are used. Forms a recess (8) having a bottom. The movable chill block (2) is provided with a pedestal (5) shown in FIGS. The number of the pedestal portions (5) may be one, but when more than the pedestal portions (5) are provided, the concave portions (8) are also formed corresponding to the number. Moreover, it is preferable to form the said recessed part (8) in the entrance side similarly to the extrusion pin (4). In addition, it is good to drill the hole for cooling water like the two-dot chain line shown in FIG. 6 in the said base part (5).

  Next, the operation of the present invention will be described with reference to FIG. First, when casting is started, the molten metal enters a cavity (not shown), gas is generated and passes through the gas vent passage (3), and the molten metal is filled into the cavity. At the same time, the molten metal enters from the inlet side of the chill block (A). At this time, the extrusion pin (4) provided on the fixed chill block (1) of the present invention is in contact with the convex portion (51) of the base (5), and the tip of the extrusion pin (4) is fixed chill block. It is flush with the hole (11) in (1) [see FIG. 4 (a)].

  After the molten metal is solidified, the mold is opened and the chill block (A) is opened together. When the cast product is taken out, when the movable chill block (2) is lowered, the push pin (4) is an elastic body (6) of the spring. As shown in FIG. 4 (b), the solidified metal is extruded from the fixed chill block (1) as shown in FIG. 4 (b). And a gap is formed between the fixed chill block (1) and the solidified metal. At this time, the solidified metal is pushed out by the extruding pin (4), and when the molten metal solidifies, it adheres to the base (5) side with a small inclination angle, so that the solidified metal peels off from the fixed chill block (1). It becomes easier. When casting with the fixed chill block on the top and the movable chill block on the bottom, when the mold is opened, the solidified metal is generally peeled off from the fixed chill block (1) and is likely to fall. If the solidified metal adheres to the fixed chill block (1), the solidified metal will surely fall if it is peeled off from the fixed chill block (1) by applying a small force. Thus, if there is a little extrusion of the extrusion pin (4), the solidified metal peels from the fixed chill block (1).

  When the movable chill block (2) is further lowered, the solidified metal adheres to the surface of the movable chill block (2) as shown in FIG. 4 (c). Thus, the solidified metal is peeled off from the movable chill block (2) and taken out to the outside of the chill block (A), that is, in the direction of the white arrow. At this time, the solidified metal adhering to the movable chill block (2) is forcibly pushed out by an unillustrated extrusion pin and taken out.

  Next, the operation of another invention will be described with reference to FIG. First, as shown in FIG. 7A, when the molten metal enters the gas vent passage (3) and solidifies, when the movable chill block (2) is lowered as in the above operation, the solidified metal has an inclination angle. It adheres to the small base part (5) side and is peeled off from the fixed chill block (1) as shown in FIG. 7B, so that a gap is formed between the fixed chill block (1). At this time, if the movable chill block (2) having a hole for cooling water, such as a two-dot chain line in the figure, is used, the periphery of the base part (5) is cooled. ), The solidified metal adheres more reliably around the fixed chill block (1).

  When the movable chill block (2) is further lowered, the solidified metal adheres to the surface of the movable chill block (2) as shown in FIG. 7 (c). In this way, the solidified metal is peeled off from the movable chill block (2) and taken out outside the chill block (A), that is, in the direction of the white arrow in the same manner as the above operation.

  As described above, the present invention is a mechanism in which the push pin (4) can be protruded and returned with a very simple structure to the fixed chill block (1), so that the maintenance management does not take time and the fixed chill block ( The solidified metal was reliably removed from 1). Moreover, even if the invention of another embodiment has a simpler structure, the solidified metal can be reliably taken out from the fixed chill block (1).

A Chill block 1 Fixed chill block
11 holes
13 Taper hole 2 Movable chill block 3 Gas vent passage 4 Extrusion pin 5 Base
51 Convex part 6 Elastic body 8 Concave part

Claims (5)

  In the chill block (A) provided with a wave-shaped gas vent passage (3) continuous on the opposed surfaces of the fixed chill block (1) and the movable chill block (2), the fixed chill block (1) includes at least A die casting chill block comprising an extrusion pin (4) for extruding the solidified metal solidified in the gas vent passage (3) so as to protrude.   The trapezoidal base part (5) which made the convex part (51) contact | abutted to a part of front-end | tip of the said extrusion pin (4) project in the center was provided in the surface of the said movable chill block (2). The die-cast chill block according to 1.   The chill block for die-casting according to claim 1 or 2, wherein an elastic body (6) for extruding the extrusion pin (4) by an elastic force is disposed in the fixed chill block (1).   A hole (11) for sliding the extruding pin (4) is formed in the fixed chill block (1), and the outer edge of the hole (11) has an inclination angle greater than that of the platform (5). The chill block for die-casting according to claim 2, wherein a tapered hole (13) having a large inclination angle is provided. In the chill block (A) having a wave-shaped gas vent passage (3) continuous on the opposed surfaces of the fixed chill block (1) and the movable chill block (2), the movable chill block (2) includes: A trapezoidal base portion (5) is provided on the surface, and a tapered concave portion (8) having an inclination angle larger than the inclination angle of the base portion (5) while being opposed to the base portion (5), A die-cast chill block provided on the fixed chill block (1).

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