JP2005046864A - Die cooling structure and die cooling method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a die cooling structure, by which molten metal filled in a cavity can be efficiently cooled and which prevents the occurrence of deformation and cracks at a part being the part of a die for demarcating the cavity where a cooling medium flow path is formed during filling the molten metal, and a die cooling method. <P>SOLUTION: The die cooling structure is provided with a fixed die 1. A fixed die 12 and a manifold block 14 are stored/fixed inside the fixed die 1. A cooling block 13 is stored/fixed inside the fixed die 12. An arcuate protruding part 13D, which is engaged with an arcuate recessed part formed to the fixed die 12, is provided to the cooling block 13. A plurality of radial protruding parts, which are brought into contact with the inner face of the fixed die 12 for demarcating the arcuate recessed part, are provided to the tip of the arcuate protruding part. The radial protruding parts partially partition off a cooling medium passage demarcated with the arcuate protruding part and the inner face of the fixed die 12. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a mold cooling structure and a mold cooling method, and in particular, a cooling medium flow path is formed at a predetermined position in the mold, and the predetermined medium in the mold is flowed through the cooling medium flow path. The present invention relates to a mold cooling structure for cooling the position and the entire mold, and a mold cooling method performed using the cooling structure.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is known a mold cooling structure in which a cooling medium flow path is formed in a mold, and the mold is cooled by flowing a cooling medium such as oil or water into the cooling medium flow path.
[0003]
International Publication No. WO 02/00375 pamphlet describes a die-cast mold cooling structure in which a cooling medium flow path is formed in a mold. The die-cast mold cooling structure includes a fixed mold having a fixed die and a movable mold having a movable die, and a cavity is defined by the movable die and the fixed die. The dividing surface that defines the cavity of the fixed die and the movable die has an uneven portion that follows the surface shape of the cast product, and is on the back surface opposite to the surface that defines the cavity of the fixed die and the movable die. Each has a deep groove portion. Concavities and convexities are formed at the positions corresponding to the concave and convex portions of the deep groove portion, following the shape of the concave and convex portions, and thereby the thicknesses of the fixed die and the movable die at the positions corresponding to the concave and convex portions are substantially constant.
[0004]
In addition, partition plates are respectively provided in the deep groove portions on the back surfaces of the fixed die and the movable die, and the portions of the partition plate facing the positions corresponding to the uneven portions are formed with uneven portions following the shape of the uneven portions. . Therefore, a cooling medium flow path defined by the fixed die and the movable die and the partition plate is defined between the fixed die and the movable die and the partition plate, and the positions of the uneven portions of the fixed die and the movable die are defined. In FIG. 5, the shape of the cooling medium flow path follows the shape of the uneven portion. For this reason, the position of an uneven | corrugated | grooved part can be efficiently cooled by flowing a cooling medium in a cooling medium flow path.
[0005]
Japanese Patent Application Laid-Open No. 5-329610 discloses a cooling structure for a mold for molten metal forging having a cooling block in the mold. The cooling block is provided in each of the movable mold and the fixed mold, and is movable in the movable mold and the fixed mold. A cooling medium flow path is formed in the cooling block. When pouring the molten metal into the cavity, the cooling block is arranged at a predetermined distance from the partition wall that forms the fixed die and the movable die and defines the cavity. The molten metal in the cavity can be cooled via the partition wall by causing the cooling medium to flow through the cooling medium flow path in the cooling block.
[0006]
[Patent Document 1]
International Publication No. WO 02/00375 pamphlet (pages 8 to 12, FIG. 3, FIG. 5, FIG. 6)
[Patent Document 2]
JP-A-5-329610 (pages 2 to 4, FIG. 1)
[0007]
[Problems to be solved by the invention]
However, in the die-cast mold cooling structure described in JP-A-5-329610, a cooling block is provided at a position inside the mold of the partition wall, so that the cooling block is in contact with the partition wall. However, the distance from the cooling medium flow path in the cooling block to the cavity inevitably increases, and the desired position of the mold cannot be efficiently cooled.
[0008]
In addition, as in the die-cast mold cooling structure described in WO 02/00375 pamphlet, in order to efficiently perform cooling, the thickness of the uneven portion of the fixed die and the movable die constituting the cavity is reduced. When the distance from the cavity to the cooling medium flow path is made as short as possible in the shape following the uneven portion, there is a problem that the uneven portion is deformed or cracked by the casting pressure when the casting pressure is high. .
[0009]
Therefore, the present invention can efficiently cool the molten metal filled in the cavity, and at the time of filling the molten metal, the portion of the die that defines the cavity and the portion where the cooling medium flow path is formed is deformed. An object of the present invention is to provide a mold cooling structure that prevents this and a mold cooling method that is performed using the cooling structure.
[0010]
[Means for Solving the Problems]
To achieve the above object, the present invention comprises a mold 1, 1 ′ comprising a holder 11 and dies 12, 12 ′ fixed to the holder 11, the dies 12, 12 ′ defining a cavity. A cooling block housing space 12b is formed in the mold 1, 1 ', and a cooling block 13, in which cooling medium flow paths 13a, 31a, 32a, 32b, 32c, 33a, 33b, 33c are formed, In the mold cooling structure in which 13 'is housed and fixed in the cooling block housing space 12b, the cooling block housing space 12b follows the concave and convex shape of the cavity, and the cavity equivalent part 12a of the dies 12, 12' And a part of the cooling blocks 13, 13 'are accommodated in the cavity copying space 12c, and the cooling blocks 13, 13' Cooling medium passages 13f and 13f ′ are provided between a part and the cavity copying space portion 12c, and the cooling medium passages 13f and 13f ′ are provided in the cooling medium passages 13a, 31a, 32a, 32b, 32c, 33a, 33b, 33c, and at least one protrusion 13E-13I, 13E'-13G 'is in contact with the inner surface of the die defining the cavity scanning space 12c from the part of the cooling block 13, 13'. A die cooling structure is provided in which the cooling medium passages 13f and 13f 'are partially partitioned by being individually provided.
[0011]
Here, a manifold block housing space 12 i that communicates with the cooling block housing space 12 b and opens to the outside of the at least one die 1 is formed inside the at least one die 1. In the space 12i, a manifold block 14 having manifold channels 14a, 14a 'formed therein is adjacent to the cooling blocks 13, 13' and the cooling medium channels 13a, 31a of the cooling blocks 13, 13 '. 32a, 32b, 32c, 33a, 33b, 33c so that the manifold channels 14a, 14a 'are in direct communication with each other, and a cooling medium supply pipe and a cooling medium discharge pipe are provided from the outside of the molds 1, 1'. It is preferable to be connected to the manifold channels 14a and 14a ′.
[0012]
The manifold block accommodation space 12b opens to the side surface 11A of the holder 11 of the at least one mold 1, and the outer end 14C of the manifold block 14 accommodated in the manifold block accommodation space 12b It is preferable that it is substantially flush with the outer surface 11A of 11 or located inward of the outer surface of the holder.
[0013]
The present invention also includes a movable mold including a movable holder and a movable die fixed to the movable holder, and a fixed mold 1 including a fixed holder 11 and fixed dies 12 and 12 ′ fixed to the fixed holder 11. A cooling block housing space 12b is formed in at least one of the movable mold and the fixed mold 1, 1 ′, and the cooling medium flow paths 13a, 31a, 32a, 32b, 32c, 33a, 33b are formed therein. In the mold cooling structure in which the cooling blocks 13 and 13 'formed with 33c are accommodated in the cooling block accommodating space 12b, the cooling block accommodating space is disposed inside the at least one mold 1, 1'. A manifold block accommodating space 12i is formed which communicates with 12b and opens to the outside of the at least one mold 1, 1 '. The manifold block 14 having manifold channels 14a and 14a 'formed therein is adjacent to the cooling blocks 13 and 13' and is connected to the cooling medium channels 13a and 13a 'of the cooling blocks 13 and 13'. The manifold channels 14a and 14a 'are accommodated so as to communicate directly, and a cooling medium supply pipe and a cooling medium discharge pipe are connected to the manifold channels 14a and 14a' from outside the molds 1 and 1 '. A mold cooling structure is provided.
[0014]
The present invention also provides a mold cooling method performed using the mold cooling structure.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
A mold cooling structure and a mold cooling method according to a first embodiment of the present invention will be described with reference to FIGS. More specifically, the mold cooling structure is a die-cast mold cooling structure, and is fixed to the fixed mold 1 as shown in FIG. A movable mold (not shown). As shown in FIG. 1, the fixed mold 1 includes a fixed holder 11 and a fixed die 12, and the fixed die 12 is fixed to the fixed holder 11.
[0016]
Similar to the fixed mold 1, the movable mold (not shown) includes a movable holder (not shown) and a movable die (not shown), and the movable die is fixed to the movable holder. A movable die (not shown) approaches the fixed die 12, and the movable die and the fixed die 12 come into contact with each other to form a cavity and perform casting. 1 to 3 show a cut model in which a part of the fixed holder 11 and the fixed die 12 are cut out for convenience of explanation. In practice, the fixed die 12 is provided in the fixed holder 11. The fixed die 12 is housed and fixed, and the periphery of the fixed die 12 is surrounded by a fixed holder 11 as indicated by a broken line in FIGS.
[0017]
As shown in FIGS. 4 to 6, the fixed die 12 has a substantially rectangular parallelepiped shape, and one surface of the fixed die 12 forms a dividing surface 12 </ b> A to define a cavity.
Accordingly, the dividing surface 12A is provided with two concavo-convex portions 12a that follow the shape of a cast product including a substantially circular concave portion and a convex portion provided at the central position thereof. Similarly, the movable die (not shown) has a substantially rectangular parallelepiped shape, and one surface of the movable die (not shown) forms a split surface provided with two concave and convex portions to define a cavity. The two uneven portions 12a are provided because this mold is a so-called two-piece type capable of casting two cast products simultaneously.
[0018]
As shown in FIG. 5, a cooling block housing space 12b is formed on the back surface 12B facing the dividing surface 12A of the fixed die 12 having a substantially rectangular parallelepiped shape. The cooling block housing space 12b is formed by drilling and has a substantially rectangular parallelepiped shape that is recessed from the back surface 12B in the direction of the dividing surface 12A, and matches the outer shape of a cooling block 13 that has a substantially rectangular parallelepiped shape to be described later. The cooling block 13 is accommodated and fixed in the cooling block accommodation space 12b. Two cooling block accommodation spaces 12 b are formed at the left and right positions of the fixed die 12 shown in FIG. 5, and open to the left and right side surfaces of the fixed die 12 and open toward the back surface 12 </ b> B of the fixed die 12. .
[0019]
Further, as shown in FIG. 5, a fixed die in a direction connecting the divided surface 12A (FIG. 4) and the back surface 12B (FIG. 5) is located at a position corresponding to the uneven portion 12a (FIG. 4) in the cooling block housing space 12b. An arcuate recess 12c that follows the shape of the concavo-convex portion 12a is formed so that the thickness of 12 is thin. The arc-shaped recess 12c is formed by drilling so as to be recessed from the back surface 12B toward the dividing surface 12A, and forms two symmetrical arc shapes in which the annular recess is divided into two at the diameter position. ing.
The thickness of the fixed die 12 at the bottom position, which is the position closest to the dividing surface 12A in the arc-shaped concave portion 12c, is 4 mm to 10 mm, which is significantly thinner than the conventional thickness of 15 mm to 20 mm. The arcuate recess 12c corresponds to a cavity copying space.
[0020]
An annular oil seal O-ring that is much shallower than the arcuate recess 12c is disposed at a position radially outward of the arcuate recess 12c so as to surround the arcuate recess 12c coaxially with the arcuate recess 12c. A groove 12d is formed. When the cooling block 13 is accommodated in the cooling block accommodation space 12b, an O-ring (not shown) is fitted in the oil seal O-ring groove 12d in advance, and the O-ring is sandwiched between the cooling block 13 and the fixed die 12. Thus, the cooling medium flowing in an arcuate recess 12c that forms a cooling medium passage 13f, which will be described later, can be sealed so that it does not flow out radially outward of the arcuate recess 12c from the position of the O-ring. .
[0021]
Further, as shown in FIG. 6, a plurality of fixed die flow paths 12 e are formed inside the fixed die 12. The fixed die flow path 12e is branched inside the fixed die 12, and by cooling a predetermined position of the fixed die 12, it is possible to effectively cool a predetermined position of the molten metal filled in the cavity. It is configured to be able to. Some branched fixed die flow paths 12e have openings 12f and 12g that open toward the cooling block housing space 12b. As shown in FIGS. 4 to 6, an opening is formed on the side surface of the fixed die 12, but this is a hole for forming the fixed die flow path 12 e, and is formed from the fixed die flow path 12 e to the outside. A plug wrapped with a sealing tape is inserted so that the cooling oil does not flow out.
[0022]
In addition, a manifold block accommodation space 12i that communicates with the cooling block accommodation space 12b and opens to the outside of the fixed holder 11 is formed inside the fixed holder 11 (FIG. 1). The manifold block 14 is accommodated.
[0023]
As shown in FIGS. 7 to 9, the cooling block 13 has a substantially rectangular parallelepiped shape that matches the shape of the cooling block accommodation space 12 b (FIG. 5). As shown in FIGS. 1 to 3, when the two cooling blocks 13 are housed and fixed in the cooling block housing space 12 b, the back surface 13 </ b> A (FIG. 8) of the cooling block 13 is the back surface 12 </ b> B ( 5), the rear surface 13A of the cooling block 13 does not protrude from the rear surface 12B of the fixed die 12, and is configured to be a flat surface as a whole. The cooling block 13 is fixed in the cooling block housing space 12 b by sandwiching the cooling block 13 between the fixed die 12 and the fixed holder 11.
[0024]
7 to 9, the cooling block 13 and the manifold block 14 described later are illustrated as if they were integrated, but this is because the cooling block 13 and the manifold block 14 are connected to the fixed die 12. These are shown for explaining the positional relationship when they are housed and fixed, and the cooling block 13 and the manifold block 14 are configured separately.
[0025]
As shown in FIG. 9, a cooling medium flow path 13 a forming a cooling medium flow path is formed inside the cooling block 13. As shown in FIG. 7, the cooling medium flow path 13 a has openings 13 b and 13 c that open on a fixed die facing surface 13 C that faces the fixed die 12 when the cooling block 13 is accommodated in the fixed die 12. There is something to have. When the cooling block 13 is housed in the cooling block housing space 12b, the fixed die flow path 12e (FIG. 6) in the fixed die 12 that opens toward the cooling block housing space 12b has an opening 12f and an opening 12g. By being connected to the opening 13b and the opening 13c (FIG. 7) of the cooling medium flow path 13a, respectively, the cooling medium flow path 13a opened in the fixed die facing surface 13C is directly communicated. As shown in FIGS. 7 to 9, an opening is formed on the side surface of the cooling block 13, but this is a hole for forming the cooling medium flow path 13a, from the cooling medium flow path 13a. A plug wrapped with sealing tape is inserted so that the cooling oil does not flow outside.
[0026]
As shown in FIG. 7, when the cooling medium flows in the opening of the cooling medium flow path 13a on the fixed die facing surface 13C as will be described later, the cooling medium flow path 13a of the cooling block 13 is fixed to the fixed die flow path. There are an opening 13b serving as an outlet that flows to 12e and an opening 13c serving as an inlet that flows from the fixed die channel 12e to the cooling medium channel 13a of the cooling block 13. An annular recess is formed around the opening position of the opening 12f and the opening 12g (FIG. 6) of the fixed die flow path 12e connected to these, and an O-ring (not shown) is formed in the annular recess. It is inserted. The O-ring (not shown) is sandwiched between the fixed die 12 and the cooling block 13 when the cooling block 13 is accommodated in the cooling block accommodating space 12b, so that the cooling medium flow channel 13a and the fixed die flow channel 12e are formed. The flowing cooling medium is configured to prevent leakage between the fixed die facing surface 13 </ b> C (FIG. 7) and the fixed die 12 that face and contact each other.
[0027]
As shown in FIGS. 7 and 9, the fixed die facing surface 13 </ b> C facing the fixed die 12 when the cooling block 13 is accommodated in the fixed die 12 has the outer shape of the arc-shaped recess 12 c of the fixed die 12. Two substantially arcuate convex portions 13D that are substantially the same are provided. The arc-shaped convex portion 13D engages with the arc-shaped concave portion 12c when the cooling block 13 is accommodated in the fixed die 12. As shown in FIG. 10, the cooling medium flow path 13a formed in the cooling block 13 also opens at both ends of the two arc-shaped convex portions 13D.
[0028]
As shown in FIG. 10, the ends of the two arc-shaped protrusions 13D protrude in the axial direction of the arc-shaped protrusion 13D, that is, in the radial direction of the arc-shaped protrusion 13D. Radial protrusions 13E to 13I extending radially are provided at intervals of approximately 5 mm in the circumferential direction of the arcuate protrusion 13D. In FIG. 1, FIG. 2, FIG. 7, and FIG. 9, the radial convex portions 13E to 13I, the outer circumferential circumferential concave portion 13d and the inner circumferential circumferential concave portion 13e, which will be described later, are omitted for ease of viewing the drawings. ing. Further, on the outer peripheral edge and the inner peripheral edge of the tip of the two arc-shaped convex portions 13D, the outer circumferential circumferential concave portion 13d that is recessed in the axial direction of the arc-shaped convex portion 13D, that is, in the back of the paper surface of FIG. Inner circumferential recesses 13e are formed respectively. In FIG. 10, for convenience of explanation, the arc-shaped convex portion 13 </ b> D is enlarged and illustrated in the radial direction.
[0029]
The outer circumferential recess 13d is formed along the outer peripheral edge of the two arc-shaped protrusions 13D from the first radial protrusion 13E to the third radial protrusion 13G, counting from the right side of FIG. ing. Moreover, it forms along the outer periphery part of the circular-arc-shaped convex part 13D from the 3rd radial convex part 13G from the right side to the 5th radial convex part 13I. The radial protrusions 13E to 13I correspond to protrusions.
[0030]
The inner circumferential direction concave portion 13e is located from the rightmost end of the inner peripheral edge of the arc-shaped convex portion 13D to the second radial convex portion 13F counted from the right, and from the second radial convex portion 13F from the right side. The position of the arc-shaped convex portion 13D at the position up to the fourth radial convex portion 13H and the position from the fourth radial convex portion 13H from the right to the leftmost end of the inner peripheral edge of the arc-shaped convex portion 13D. It is formed along the inner periphery.
[0031]
Since the inner circumferential recess 13e is formed, the first, third, and fifth radial projections 13E, 13G, and 13I counting from the right side of FIG. 10 are more circular than the inner circumferential surface 13K of the arc-shaped projection 13D. The arc-shaped convex portion 13D has a shape extending from a predetermined position on the outer side in the radial direction to the outer peripheral surface 13J, and is not provided in the vicinity of the inner peripheral surface 13K. Further, the second and fourth radial convex portions 13F and 13H counted from the right side of FIG. 10 are located radially inward of the arc-shaped convex portion 13D from the inner peripheral surface 13K of the arc-shaped convex portion 13D than the outer peripheral surface 13J. The shape extends to a predetermined position, and is not provided at a position near the outer peripheral surface 13J.
[0032]
Therefore, as described above, when the cooling block 13 is housed and fixed in the cooling block housing space 12b, the two arc-shaped convex portions 13D engage with the two arc-shaped concave portions 12c, respectively. The arc-shaped convex portion 13D is a back surface of the fixed die 12 in which only the radial convex portions 13E to 13I, the inner peripheral surface 13K of the arc-shaped convex portion 13D, and the outer peripheral surface 13J of the arc-shaped convex portion 13D define the arc-shaped concave portion 12c. It contacts 12B (inner surface).
[0033]
On the other hand, the positions where the inner circumferential circumferential concave portion 13e and the outer circumferential circumferential concave portion 13d of the arc-shaped convex portion 13D are recessed in the axial direction of the arc-shaped convex portion 13D. Does not touch In addition, the arc-shaped convex portion 13 </ b> D where the radial convex portions 13 </ b> E to 13 </ b> I are not provided does not contact the inner surface of the fixed die 12. Therefore, the inner surface of the fixed die 12 and the arc-shaped convex portion 13D define a space that communicates in a zigzag manner between the radial convex portions 13E to 13I, as indicated by an arrow A in FIG. . This space forms a cooling medium passage 13f, and the cooling medium passage 13f is partially partitioned by the radial protrusions 13E to 13I.
[0034]
As shown in FIGS. 7 to 9, the manifold block 14 is configured by a block body having an octagonal cross section, a base end portion 14 </ b> A thick, and a tip end portion 14 </ b> B slightly thinner than the base end portion 14 </ b> A. The outer shape of the manifold block 14 matches the outer shape of the manifold block accommodation space 12i (FIG. 1) that accommodates the manifold block 14, and opens to the side surface 11A of the fixed holder 11 as shown in FIGS.
When the manifold block 14 is housed in the manifold block housing space 12i, the entire manifold block 14 is housed in the fixed holder 11, and the end surface 14C of the base end portion 14A of the manifold block 14 faces the side surface 11A of the fixed holder 11. Become one.
[0035]
As shown in FIG. 9, a manifold channel 14 a for flowing a cooling medium is formed inside the manifold block 14. The manifold channel 14a opens at the end surface 14C of the base end portion 14A and the end surface 14D of the distal end portion 14B. When the manifold block 14 and the cooling block 13 are accommodated and fixed in the stationary mold 1, the manifold block 14 is disposed adjacent to the cooling block 13, and all the manifold channels 14a are cooled at the tip portion 14B. It communicates directly with the medium flow path 13a. Further, all the manifold channels 14 a open at the base end portion 14 </ b> A and open at the side surface 11 </ b> A of the fixed holder 11.
[0036]
Although the configuration of the fixed mold 1 has been described in detail above, the movable mold is provided with the cooling block 13 and the manifold block 14 in the same manner as the fixed mold 1, and has the same configuration as the fixed mold 1.
[0037]
In the mold cooling method performed at the time of casting, first, the fixing holder 11 which accommodates the fixed die 12 in which the cooling block 13 is accommodated in the cooling block accommodating space 12b and the manifold block 14 is accommodated in the manifold block accommodating space 12i. In contrast, a cooling medium supply pipe and a cooling medium discharge pipe (not shown) are respectively connected. Specifically, since the end surface 14C of the base end portion 14A of the manifold block 14 is exposed on the side surface 11A of the fixed holder 11, that is, the side surface of the fixed mold 1, a predetermined manifold flow that opens to the end surface 14C is exposed. A cooling medium supply pipe may be connected to the path 14a, and a cooling medium discharge pipe may be connected to the other manifold flow path 14a.
[0038]
Next, cooling oil which is a cooling medium is supplied from a cooling medium supply pipe (not shown). The cooling oil supplied from the cooling medium supply pipe flows through the manifold channel 14 a and flows into the cooling medium channel 13 a in the cooling block 13. And it changes into a turbulent state from a laminar flow state by flowing in into cooling-medium channel | path 13f from the opening of the one end of circular-arc-shaped convex part 13D, and as shown by arrow A of FIG. 10, radial convex part 13E-13I. The portion of the arcuate recess 12c of the fixed die 12 is cooled by flowing in a zigzag manner. Then, it flows into the cooling medium flow path 13a in the cooling block 13 from the opening at the other end of the arc-shaped convex portion 13D, flows in the cooling medium flow path 13a, flows in the manifold flow path 14a, and the cooling medium (not shown) It flows into the discharge pipe.
[0039]
The cooling medium flow path 13a is branched in the cooling block 13, and a part of the cooling oil flows in the cooling medium passage 13f as described above, but the other part is a fixed die flow formed in the fixed die 12. It flows into the path 12e. The cooling oil that has flowed into the fixed die flow path 12e flows through the fixed die flow path 12e to cool a predetermined position of the fixed die 12, and then flows into the cooling medium flow path 13a in the cooling block 13. It flows through the flow path 14a and flows out to a cooling medium discharge pipe (not shown).
[0040]
The flow path for flowing the cooling medium to the fixed die flow path 12e in the fixed die 12 and the cooling medium path 13f is constituted by the cooling medium flow path 13a formed in the cooling block 13, and further adjacent to the cooling block 13. Since the manifold block 14 is provided and the manifold channel 14a is connected to the cooling medium channel 13a to flow the cooling medium, it is possible to reduce the number of components without using a piping component hose that has been conventionally used. In addition, it is possible to prevent the deterioration of reproducibility caused by the cross-sectional collapse of the flow path and the difference in the set length, and the reproducibility can be extremely enhanced.
[0041]
That is, when the cooling medium supply pipe and the cooling medium discharge pipe are directly connected to the cooling medium flow path 13a of the cooling block 13 without using the manifold block 14, it is necessary to connect a pipe to the cooling block 13. There may be variations depending on the work conditions of the worker. On the other hand, by adopting the manifold block 14, there is no variation in work, and a stable flow path connection can always be made.
[0042]
Further, when performing die casting, a very strong mold closing force acts on the fixed mold 1 and the movable mold. Conventionally, since the hole for inserting the cooling pipe toward the cavity is formed from the surface opposite to the cavity side surface of the fixed holder 11 and the movable holder, it is difficult to maintain the mold strength. There was a gap in the hit. However, since the cooling medium is supplied using the cooling block 13 and the manifold block 14, the mold strength can be maintained and the hit can be secured. Furthermore, since the cooling block 13 is housed and fixed as a block body in the cooling block housing space 12b, the mechanical strength of the entire mold can be maintained at a high level.
[0043]
In addition, since it is not necessary to provide piping on the back side of the mold, for example, on the rear surface of the movable holder, it is possible to reduce a space for avoiding interference with the rear periphery particularly when the movable mold is moved. Further, since the end surface 14C of the base end portion 14A of the manifold block 14 is flush with the side surface 11A of the fixed holder 11, the entire mold can be made more compact.
[0044]
Further, the inner surface of the fixed die 12 is formed into an arcuate recess 12c that follows the shape of the cavity side surface, and the arcuate recess 12c and the arcuate protrusion 13D communicate with each other so as to sew the radial protrusions 13E to 13I. Since the cooling medium passage 13f is defined, the portion of the arc-shaped recess 12c of the fixed die 12 can be sufficiently cooled. Further, since the radial convex portions 13E to 13I are in contact with the inner surface of the fixed die 12, the radial convex portions 13E to 13I can play a role like a beam to support the inner surface of the fixed die 12, and the arc-shaped concave portion 12c. Even if the thickness of the fixed die 12 at the bottom of the plate is 4 mm to 10 mm and much thinner than the conventional 15 mm to 20 mm, it can withstand casting pressure and prevent deformation and cracking. . For this reason, in the position of the circular arc-shaped recessed part 12c used as high temperature, a cooling effect can be improved significantly and the heat capacity of the fixed metal mold | die 1 and a movable metal mold | die can be made low as much as possible.
[0045]
For this reason, a cooling oil having a relatively low heat transfer coefficient can be used as the cooling medium. When cooling water is used compared to cooling oil, there are drawbacks such as clogging of the cooling medium due to scale or the boiling of the cooling medium, resulting in a significant decrease in cooling performance. There are no such drawbacks. Cooling oil is preferable to cooling water from the viewpoint of reproducibility. However, in the case of cooling oil, the heat transfer coefficient is low. However, as described above, since the thickness of the fixed die 12 at the bottom of the arcuate recess 12c can be reduced, the cooling effect can be sufficiently exerted. In addition, since the radial convex portions 13E to 13I extending radially in the radial direction of the arc-shaped convex portion 13D are provided at intervals of approximately 5 mm toward the circumferential direction of the arc-shaped convex portion 13D, respectively. Since the cooling medium flows between the radial protrusions 13E to 13I so as to sew and the flow rate of the cooling medium can be increased, the cooling effect can be further enhanced.
[0046]
Further, since the radial convex portions 13E to 13I partially partition the cooling medium passage 13f, the cooling medium flowing in the cooling medium passage 13f can be changed from a laminar flow state to a turbulent flow state, and the cooling effect can be enhanced. it can. In particular, by providing a plurality of radial protrusions 13E to 13I in the cooling medium passage 13f so that the refrigerant meanders between the radial protrusions 13E to 13I, the effect can be further enhanced.
[0047]
Next, a mold cooling structure and a mold cooling method according to a second embodiment of the present invention will be described with reference to FIG. More specifically, the mold cooling structure according to the second embodiment is a die-cast mold cooling structure in that the cooling block 13 'is formed by superposing three plate-like members 31, 32, and 33. This is different from the mold cooling structure according to the first embodiment.
[0048]
As shown in FIG. 11, a fixed mold 1 ′ constituting a die-cast mold cooling structure includes a fixed holder (not shown), a fixed die 12 ′ received and fixed in a fixed holder (not shown), and a cooling block 13. ′ And a manifold block (not shown).
The cooling block 13 'is composed of three plate-like members composed of a first plate member 31, a second plate member 32, and a third plate member 33, which are overlapped as shown in FIG. As a result, one cooling block 13 'is formed. Further, a manifold block (not shown) is disposed in contact with the cooling block 13 'at a predetermined position in front of the paper surface in FIG. 11 and adjacent to the end face of the cooling block 13'. The fixed die 12 'and the cooling block 13' are not exactly the same shape as the fixed die 12 and the cooling block 13 of the mold cooling structure according to the first embodiment, and are slightly different in shape.
[0049]
The first plate member 31 is formed with a passage 31a extending in the front direction of the paper surface of FIG. The passage 31a is open on the end face of a cooling block (not shown) that is in front of the paper surface in FIG. A pipe member 14E that defines a manifold channel 14a 'formed in a manifold block (not shown) is inserted into the opening position. The passage 31a bends vertically in the middle and extends downward in FIG.
[0050]
The 1st groove | channel 32c is formed in the back surface of the 2nd board member 32 contact | abutted with the 1st board member 31, and when the 1st board member 31 and the 2nd board member 32 are piled up, the 1st groove | channel 32c is overlapped. To the passage 31a. The first groove 32c is branched in the middle on the back surface of the second plate member 32 in order to flow the cooling medium to a predetermined position on the back surface of the second plate member 32, and the predetermined groove of each of the branched grooves A through hole 32 a is formed at the position so as to penetrate the surface side of the second plate member 32 that contacts the third plate member 33. Further, the second plate member 32 is formed with a through hole 32b that penetrates toward the surface side of the second plate member 32 and is different from the through hole 32a.
[0051]
A through hole 33 a is formed in the third plate member 33, and the through hole 33 a opens at a position in the vicinity of the base end of the convex portion 13 </ b> D ′ provided on the surface with respect to the back surface in contact with the second plate member 32. The through hole 33 a communicates with the through hole 32 a formed in the second plate member 32 when the second plate member 32 and the third plate member 33 are overlapped.
[0052]
Further, a second groove 33 c is formed on the back surface of the third plate member 33 that contacts the second plate member 32. Similarly to the first groove 32c, the second groove 33c is branched on the back surface, and a through hole 33b is formed at a predetermined position of each branched groove. The through hole 33b opens at a position in the vicinity of the base end of the convex portion 13D ′ provided on the front surface with respect to the back surface in contact with the second plate member 32.
[0053]
Further, a through hole 32b that penetrates the second plate member 32 is formed at a position where each groove of the branched second groove 33c converges, and the through hole 32b branches in the middle, 11 extends in the front direction of the paper surface in FIG. 11, and is open in the end surface of the cooling block (not shown) that exists in the front direction of the paper surface in FIG. 11 and contacts the manifold block (not shown). A pipe member 14E that defines a manifold channel 14a 'formed in a manifold block (not shown) is inserted into the opening position. The passage 31a, the through holes 32a and 32b, the first groove 32c, the through holes 33a and 33b, and the second groove 33c correspond to a cooling medium flow path.
[0054]
The outer peripheral surface of the convex portion 13D 'and the fixed die 12' are separated from each other, and the outer peripheral surface of the convex portion 13D 'and the fixed die 12' are cooled in the same manner as the cooling medium passage 13f of the first embodiment. A medium passage 13f 'is defined. As shown in FIG. 11, partition convex portions 13E ′, 13F ′, and 13G ′ are provided at the tip position of the convex portion 13D ′. For this reason, as in the first embodiment, the cooling medium passage 13f is provided. 'Is partially partitioned, and the cooling medium passage 13f' communicates so that the partition convex portions 13E 'to 13G' are sewn zigzag.
[0055]
Further, the cooling medium flowing in the cooling medium flow path 13f ′, the passage 31a, the through holes 32a and 32b, the first groove 32c, the through holes 33a and 33b, and the second groove 33c is in contact with the plate members 31 to 33. So that the cooling medium flowing in the first groove 32c does not leak from the contact surfaces of the plate members 31 to 33 to the second groove 33c. Therefore, as shown in FIG. 11, a seal member 34 is provided at a predetermined position on the contact surface of each plate member 31 to 33.
[0056]
Further, a manifold block (not shown) is disposed adjacent to the cooling block 13 ', or a manifold block channel 14a' is formed in the manifold block (not shown), and the manifold block channel 14a 'is not shown. About the point etc. which open on the side instead of the surface of a fixed holder, it is the same as that of the metal mold | die cooling structure by 1st Embodiment.
[0057]
In addition, the side surface of the fixing holder (not shown) exists at a predetermined position in the front direction of the paper surface in FIG. Further, in the cross-sectional view of FIG. 11, only one convex portion 13D ′ appears, but a plurality of convex portions 13D ′ are provided, and accordingly, a plurality of cooling medium passages 13f ′ are also formed. In addition, the fixed mold 1 ′ constituting the mold cooling structure has been described, but the cooling block is similarly constituted by three plate-like members for a movable mold (not shown) constituting the mold cooling structure. Yes.
[0058]
When the mold cooling method is performed at the time of casting, the cooling oil, which is the cooling medium flowing into the passage 31a of the first plate member 31 from the manifold channel 14a ', branches through the first groove 32c, and the second plate. It passes through the through hole 32a of the member 32 and the through hole 33a of the third plate member 33 and flows into the cooling medium passage 13f '. Then, as shown by an arrow B, it flows in the cooling medium passage 13f ′ so as to sew between the partition projections 13E ′, 13F ′, 13G ′ and passes through the through hole 33b of the third plate member 33. , Flows into the second groove 33c, passes through the through hole 32b of the second plate member 32, and flows out to the manifold channel 14a '.
[0059]
Since the cooling block 13 'is constituted by the three plate members 31, 32, 33, the passage 31a, the through holes 32a, 32b, the first groove 32c, the through hole formed in the first plate member 31 to the third plate member 33. The cooling medium flow path in the cooling block 13 ′ can be configured by 33 a and 33 b and the second groove 33 c. For this reason, the cooling medium flow path can be easily formed in the cooling block 13 ', and the manufacturing of the cooling block 13' can be facilitated.
[0060]
The mold cooling structure and the mold cooling structure according to the present invention are not limited to the above-described embodiments, and various modifications and improvements can be made within the scope described in the claims. For example, in the present embodiment, both the fixed mold 1 and the movable mold have the cooling block and the manifold block, but only one of the fixed mold 1 and the movable mold has the cooling block and the manifold. You may make it provide a block.
[0061]
The cooling block is not limited to a movable mold or a fixed mold. For example, a cooling block housing space is formed in a slide core composed of a core holder and a core die so that the cooling block is housed and fixed. May be. In this case, similarly to the first embodiment, the cooling block housing space is configured to have a cavity scanning space portion in which the cavity-corresponding portion of the core die follows the concave-convex shape of the cavity and has a thin portion, A portion of the cooling block is accommodated in the cavity scanning space, and the cooling medium passage communicates with the cooling medium flow path so that a cooling medium passage is provided between the part of the cooling block and the cavity scanning space. Configure as follows. A part of the cooling block may be provided with at least one protruding part that abuts against the inner surface of the die that defines the cavity copying space part so as to partially partition the cooling medium passage.
[0062]
Furthermore, as in the first embodiment, a manifold block may be provided adjacent to the cooling block.
[0063]
Further, the entire manifold block 14 is accommodated in the fixed holder 11, and the end surface 14C of the base end portion 14A of the manifold block 14 is configured to be flush with the side surface 11A of the fixed holder 11. The end surface of the end portion may be located inward of the outer surface of the holder.
[0064]
The number and shape of the radial convex portions 13E to 13I provided on the arc-shaped convex portion 13D, the number and shape of the outer circumferential circumferential concave portion 13d and the inner circumferential circumferential concave portion 13e, the number and shape of the convex portion 13D ′, and the partition convex portion 13E The number and shape of 'to 13G' are not limited to the number of the present embodiment.
It suffices that at least one radial projection or partition projection is provided.
[0065]
Although cooling oil was supplied as a cooling medium from a cooling medium supply pipe, it is not limited to this. Cooling water may be used.
[0066]
In addition, a groove extending along the circumferential direction of the arc-shaped convex portion is formed on the inner peripheral side surface or the outer peripheral side surface of the arc-shaped convex portion, and the cooling medium flow path is communicated with the groove so that the cooling medium flows. Good. With this configuration, since the cooling medium can flow not only at the tip of the arc-shaped convex portion but also at the position of the side surface, the entire arc-shaped concave portion of the fixed die can be efficiently cooled.
[0067]
In addition, the cooling medium flow path 13a in the cooling block 13, the manifold flow path 14a in the manifold block 14, and the fixed die flow path 12e in the fixed die 12 are formed by a plurality of types of flow paths that do not communicate with each other. The temperature of the flowing cooling oil and cooling water may be set to different values, and the cooling temperature at a desired position may be set to a desired temperature.
[0068]
Further, since the O-ring is sandwiched between the cooling block 13 and the fixed die 12, the cooling medium flowing in the arc-shaped recess 12c forming the cooling medium passage 13f is moved outward in the radial direction of the arc-shaped recess 12c from the position of the O-ring. The cooling medium flowing in the cooling medium flow path 13f is sealed so that it does not leak between the fixed die facing surface 13C of the cooling block 13 and the fixed die 12. It is not limited. However, a liquid seal (liquid gasket) is preferable as the seal member.
[0069]
In the mold cooling structure according to the second embodiment, the cooling blocks of both the fixed mold and the movable mold are configured by three plate-shaped members. One of them may be constituted by three plate-like members.
[0070]
The mold cooling structure according to the present embodiment may be a casting mold other than die casting, or may be an injection mold.
[0071]
The manifold channel may be configured to have two openings on the end face of the base end. In this case, two manifold channels that respectively branch into the manifold block are formed, one manifold channel is opened at one opening, and the opening serves as an inlet for the cooling medium, and at the other opening, Another manifold channel is opened, and the opening serves as an outlet for the cooling medium. By doing so, one cooling medium supply pipe and one cooling medium discharge pipe connected to the manifold block can be provided.
[0072]
In the present embodiment, the cooling block housing space 12b is provided in the fixed die 12. However, a part of the cooling block housing space may be formed in the die and the remaining portion may be formed in the holder.
[0073]
In addition, the cooling block 13 is fixed in the cooling block housing space 12b by sandwiching the cooling block 13 between the fixed die 12 and the fixed holder 11. A through hole is formed in the cooling block, and the through hole is formed. Bolts may be inserted into the fixed die.
[0074]
【The invention's effect】
According to the mold cooling structure according to claim 1 or the mold cooling method according to claim 5, in the die, the cavity corresponding portion of the die forms a thin wall portion following the cavity uneven shape as a part of the cooling block storage space. A cavity copying space is formed, and a part of the cooling block is accommodated in the cavity copying space, and a cooling medium passage is provided between a part of the cooling block and the cavity copying space. Can be formed in the vicinity of the cavity and following the concave and convex shape of the cavity, and the high temperature portion of the mold can be effectively cooled.
[0075]
Further, since at least one projecting portion that abuts the inner surface of the die that defines the cavity copying space portion is provided from a part of the cooling block, the space between the portion of the cooling block and the cavity copying space portion is provided. A protrusion is disposed in the defined cooling medium passage, and this protrusion serves as a support for the thin wall portion. Therefore, even if casting pressure acts on the thin wall portion, the thin wall portion is supported by the cooling block via the protrusion in the cooling medium passage, and deformation and cracking of the thin wall portion can be prevented. Here, since the cooling block is housed and fixed in the cooling block housing space as a block body, the mechanical strength of the entire mold can be maintained at a high level, and the thin wall portion can be reliably secured via the protruding portion. Can be supported.
[0076]
According to the mold cooling structure of claim 2, a manifold block housing space that communicates with the cooling block housing space and opens to the outside of at least one mold is formed inside at least one of the molds. In the block accommodating space, a manifold block having a manifold channel formed therein is accommodated adjacent to the cooling block and in direct communication with the cooling medium channel of the cooling block. The cooling block and the manifold block can be connected without intervention, and the number of parts can be reduced, and the entire apparatus can be made compact.
[0077]
According to the mold cooling structure of the third aspect, since the manifold block accommodation space is opened on the side surface of the holder of at least one mold, the cooling medium flow path extending to the back side of the mold is formed. There is no need, and the mold strength can be increased. In addition, since it is not necessary to provide piping on the back side of the mold, for example, on the rear surface of the movable holder, it is possible to reduce a space for avoiding interference with the rear periphery particularly when the movable mold is moved.
[0078]
Further, the outer end of the manifold block accommodated in the manifold block accommodating space is substantially flush with the outer surface of the holder or is located inward of the outer surface of the holder, so that the entire mold becomes more compact. .
[0079]
According to the mold cooling structure of the fourth aspect, since both the cooling block and the manifold block are accommodated in the mold as a block body, the operation reproducibility of the apparatus can be further improved. That is, when it is not a manifold block, it is necessary to connect piping to the cooling block, but there is a possibility that variations will occur depending on the work conditions of the operator. On the other hand, by adopting the manifold block, work variation does not occur, and stable flow path connection is always possible.
[0080]
When the manifold block is not used, it is necessary to connect a pipe to the cooling block, and it is necessary to form a space for the pipe in the mold. If the space is unnecessarily large, the mold strength is insufficient with respect to the casting pressure. However, since the manifold block is used, unnecessary space does not occur in the mold, so that the mold strength can be increased.
[0081]
Further, since the manifold block is accommodated in the manifold block accommodation space adjacent to the cooling block and directly connected to the cooling medium passage of the cooling block, the cooling block and the manifold block are not connected to the piping. The number of parts can be reduced, and the entire apparatus can be made compact.
[Brief description of the drawings]
FIG. 1 is a partial cross-sectional perspective view showing a fixed mold constituting a mold cooling structure according to a first embodiment of the present invention.
FIG. 2 is a partial sectional plan view showing a fixed mold constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 3 is a partial sectional side view showing a fixed mold constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 4 is a perspective view showing a fixed die constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 5 is a rear perspective view showing a fixed die constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 6 is a rear perspective view showing a fixed die flow path in the fixed die constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 7 is a perspective view showing a cooling block and a manifold block constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 8 is a rear perspective view showing a cooling block and a manifold block constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 9 is a perspective view showing a cooling block, a cooling medium flow path, and a manifold flow path in the manifold block constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 10 is a plan view showing arcuate convex portions of a cooling block constituting the mold cooling structure according to the first embodiment of the present invention.
FIG. 11 is a cross-sectional view of a main part of a fixed mold constituting a mold cooling structure according to a second embodiment of the present invention.
[Explanation of symbols]
1, 1 'fixed mold
11 Fixed holder
11A side
12, 12 'fixed die
12A Dividing surface
12a Concavity and convexity
12b Cooling block accommodation space
12c Arc-shaped recess
12i Manifold block accommodation space
13, 13 'Cooling block
13E-13I, Radial convex part
13E 'to 13G' partition projection
13a Coolant flow path
13f, 13f 'Cooling medium passage
14. Manifold
14C end face
14a Manifold flow path
31 First plate member
32 Second plate member
33 Third plate member
31a, 31b, 32a, 32b, 33a, 33b Through hole
32c 1st groove
33c Second groove

Claims (5)

A die having a holder and a die fixed to the holder; the die defines a cavity; a cooling block housing space is formed in the die; and a cooling medium flow path is formed therein. In the mold cooling structure in which the cooling block is housed and fixed in the cooling block housing space,
The cooling block accommodation space has a cavity scanning space portion that follows the concave and convex shape of the cavity and has a thin portion corresponding to the cavity of the die.
A part of the cooling block is accommodated in the cavity scanning space, and a cooling medium passage is provided between the part of the cooling block and the cavity copying space, and the cooling medium passage is provided in the cooling medium. Communicate with the flow path,
From the part of the cooling block, at least one projecting portion that abuts against the inner surface of the die that defines the cavity copying space is projected to partially partition the cooling medium passage. Mold cooling structure. A manifold block housing space that communicates with the cooling block housing space and opens to the outside of the at least one die is formed inside the at least one mold, and the manifold block housing space includes a manifold inside. A manifold block in which a flow path is formed is accommodated adjacent to the cooling block and in direct communication with the cooling medium flow path of the cooling block, and a cooling medium supply pipe from the outside of the mold The mold cooling structure according to claim 1, wherein a cooling medium discharge pipe is connected to the manifold channel. The manifold block accommodation space opens on a side surface of the holder of the at least one mold,
The outer end of the manifold block housed in the manifold block housing space is substantially flush with the outer surface of the holder or is located inward of the outer surface of the holder. The mold cooling structure as described. A movable mold having a movable holder and a movable die fixed to the movable holder; a fixed mold having a fixed holder and a fixed die fixed to the fixed holder; and the movable mold and the fixed mold In the mold cooling structure in which the cooling block housing space is formed in at least one of the inside and the cooling block in which the cooling medium flow path is formed is housed in the cooling block housing space.
A manifold block housing space that communicates with the cooling block housing space and opens to the outside of the at least one die is formed inside the at least one mold, and the manifold block housing space includes a manifold inside. A manifold block in which a flow path is formed is accommodated adjacent to the cooling block and in direct communication with the cooling medium flow path of the cooling block, and a cooling medium supply pipe from the outside of the mold And a cooling medium discharge pipe connected to the manifold flow path. A mold cooling method, which is performed using the mold cooling structure according to claim 1.

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