JP2020175447A - Metallic mold and hot press molding device - Google Patents

Abstract

To provide a metallic mold for hot press molding that allows a step of a metal plate material to be quenched too so that the material is highly hardened.SOLUTION: A metallic mold, which is used for press molding a heated metal plate material 12, comprises a refrigerant passage through which a refrigerant flows, and at least one refrigerant blowout path 64, one end of which is connected to the refrigerant passage and the other end of which is opened to a molding face of a metallic mold (a lower mold 13). The metallic mold further comprises a first molding face 51 and a second molding face 52 that separates from a molding face of the other metallic mold farther than the first molding face 51 and forms a step 53 together with the first molding face 51. The other end of the at least one refrigerant blowout port 64 is opened to the vicinity of the step 53 formed by the first molding face 51 and the second molding face 52, on the second molding face 52.SELECTED DRAWING: Figure 7

Description

The present invention relates to a mold for hot press molding and a hot press molding apparatus for molding a metal plate having a plurality of plate portions having different thicknesses while quenching.

The hot stamping method, which is one of the hot press molding methods, is known as a technique for molding the skeleton parts of a vehicle. This hot stamping method is a method in which a metal plate material heated to a high temperature is loaded into a hot press molding apparatus, and the metal plate material is press-molded and hardened at the same time. A conventional hot press molding apparatus used to carry out this kind of hot stamping method is described in, for example, Patent Document 1.

The hot press molding apparatus disclosed in Patent Document 1 includes a cooling device for cooling the mold in order to keep the temperature of the mold for molding at a low temperature.
By the way, as a metal plate material used for press molding, for example, as described in Patent Document 2, there is a tailored blank made of a plurality of plate materials having different thicknesses. This tailored blank is formed by welding a plurality of metal plate materials having different thicknesses in a state of being butted against each other. On the front surface or the back surface of the molded product molded from this type of metal plate material, a step portion due to the difference in the thickness of the plate material is formed.

Japanese Unexamined Patent Publication No. 2005-169394 Japanese Unexamined Patent Publication No. 2010-36222

A molded product molded by a hot stamping method using a metal plate material made of a plurality of plate materials having different thicknesses has a problem that the hardness becomes low at a step portion which is a boundary between the plate materials. It is considered that the reason why the hardness is lowered in this way is that the cooling by the mold is insufficient and the quenching cannot be sufficiently carried out. Here, the reason why the cooling becomes insufficient will be described with reference to FIG.

FIG. 14 shows a state in which the metal plate material 3 is molded by a pair of dies 1 and 2 for conventional hot press molding. The pair of molds 1 and 2 is composed of a lower mold (hereinafter, simply referred to as a lower mold) 1 and an upper mold (hereinafter, simply referred to as an upper mold) 2. The lower mold 1 and the upper mold 2 are cooled to a predetermined temperature by a cooling device (not shown).
In the metal plate material 3, the first plate portion 3a made of a metal plate material having a relatively thin thickness and the second plate portion 3b made of a metal plate material having a relatively thick thickness are butted against each other. It is welded in the state.

The upper surface of the metal plate material 3, that is, the surface molded by the upper mold 2, is formed flat. A step 4 is formed by the first plate portion 3a and the second plate portion 3b on the lower surface of the metal plate material 3, that is, the surface molded by the lower mold 1. The step 4 includes a first step surface 3c formed of an end surface of the second plate portion 3b.
The lower mold 1 has a first molding surface 1a for molding the first plate portion 3a and a second molding surface 1b for molding the second plate portion 3b. The second molding surface 1b is formed so as to be separated from the molding surface 2a of the upper mold 2 from the first molding surface 1a, and forms a step 5 together with the first molding surface 1a. The step 5 includes a second step surface 1c extending in the thickness direction of the first plate portion 3a. The second molding surface 1b is lower than the first molding surface 1a by a height corresponding to the difference in thickness between the first plate portion 3a and the second plate portion 3b.

The second stepped surface 1c is positioned on the first plate portion 3a side from the first stepped surface 3c, which is the boundary between the first plate portion 3a and the second plate portion 3b, by a predetermined distance. There is. Therefore, a space S having a predetermined width is formed between the first stepped surface 3c and the second stepped surface 1c in the direction along the first molding surface 1a (left-right direction in FIG. 14). There is. In the following, this space S is simply referred to as a mold relief space S. The reason why the mold relief space is formed in this way is that there is a tolerance between the lower mold 1 and the metal plate material 3, and the first plate portion 3a and the second plate portion 3b are formed with respect to the position of the boundary. This is because the position of the boundary between the molding surface 1a of 1 and the second molding surface 1b is not always constant. That is, the mold relief space S is formed in order to prevent the first molding surface 1a formed so as to be relatively higher than the lower mold 1 from hitting the relatively thick second plate portion 3b of the metal plate material 3. Has been done.
The portion of the first plate portion 3a exposed to the mold relief space S is the stepped portion of the molded product described above. Since this stepped portion is separated from the lower mold 1 and is difficult to be cooled, quenching is insufficient and the strength is lowered.

An object of the present invention is to provide a mold for hot press molding and a hot press molding apparatus in which a step portion of a metal plate material is also hardened to increase the hardness.

In order to achieve this object, the mold according to the present invention is a mold used for press molding of a heated metal plate material, in which a refrigerant passage through which a refrigerant flows and one end connected to the refrigerant passage are connected to the other. The first molding is separated from at least one refrigerant ejection path whose end opens to the molding surface of the mold, the first molding surface, and the molding surface of the mold other than the first molding surface. A second molding surface that forms a step together with the surface is provided, and the other end of the at least one refrigerant ejection path is the second molding surface of the first molding surface and the second molding surface. It is open near the step.

In the present invention, in the mold, at least one suction port into which the refrigerant is sucked may be opened in the vicinity of the other end of the refrigerant ejection path.

In the present invention, in the mold, the opening at the other end of the refrigerant ejection path and the suction port may be provided at a plurality of positions arranged along the step.

In the present invention, in the mold, at least a part of the second molding surface is formed by a large number of convex portions, and the portion of the second molding surface having the large number of convex portions has a plurality of said parts. The other end opening of the refrigerant ejection path and a plurality of the suction ports may be formed.

The hot press molding apparatus according to the present invention includes a pair of dies for press molding a heated metal plate material and a cooling device for supplying a refrigerant to at least one of the pair of dies. The mold to which the refrigerant is supplied is the mold of the present invention, and the refrigerant is supplied from the cooling device to the refrigerant passage.

In the mold and hot press molding apparatus of the present invention, in the space formed between the metal plate material and the mold at the time of molding, the first molding surface and the second molding surface of the second molding surface of the mold are provided. The other end of the refrigerant ejection path is open near the step with the molding surface. By supplying the refrigerant to this space from the refrigerant ejection path during molding, the stepped portion of the metal plate material exposed in this space can be cooled by the refrigerant.
Therefore, when the heated metal plate material is press-molded, quenching is performed even at the stepped portion of the metal plate material. Therefore, according to the present invention, it is possible to provide a mold for hot press molding and a hot press molding apparatus in which a step portion of a metal plate material is also hardened to increase the hardness.

It is a front view which shows the structure of the hot press molding apparatus provided with the mold which concerns on this invention. It is a side view which shows the structure of the mold part of the hot press molding apparatus. It is sectional drawing which shows the step part of a metal plate material enlarged. It is a top view of the lower mold according to 1st Embodiment. It is a perspective view seen from the upper die side of the lower die. It is a perspective view seen from the lower die side of the upper die. It is sectional drawing which shows the main part of the lower mold and a metal plate material in an enlarged manner. It is a perspective view which shows by breaking a part of the lower mold. It is a perspective view which shows by breaking a part of the lower mold. It is a graph which shows the experimental result which verified this invention. It is a perspective view of the lower mold by the 2nd Embodiment. It is a perspective view which shows the part of the molding surface of the lower mold enlarged. It is sectional drawing which shows the deformation example of the spout of the main part of the lower mold. It is sectional drawing of a part of the conventional hot press molding die and a metal plate material.

(First Embodiment)
Hereinafter, an embodiment of the mold and the hot press molding apparatus according to the present invention will be described in detail with reference to FIGS. 1 to 11.
The hot press molding apparatus 11 shown in FIG. 1 molds a metal plate material 12 (see FIG. 2) by a hot stamping method, and has a molding portion 15 including a pair of dies 13 and 14 and these dies 13. It is composed of a cooling unit 22 connected to 14 via a plurality of pipes 16 to 21.
In the following, in showing the direction in explaining the configuration of the hot press molding apparatus 11, for convenience, the front side of the paper surface of FIG. 1 will be the front side, and the back side of the paper surface of FIG. 1 will be the rear side. Further, when the hot press molding apparatus 11 shown in FIG. 1 is viewed from the front side, the upper side will be described as the upper side of the hot press molding apparatus 11, and the right side will be described as the right side of the hot press molding apparatus 11.

The pair of molds 13 and 14 are a lower mold (hereinafter, simply referred to as a lower mold) 13 and an upper mold (hereinafter, simply referred to as an upper mold) 14. The lower mold 13 is attached to the base 24 of the molding portion 15 via the lower mold holder 23. A plurality of guide rods 25 extending in the vertical direction are erected on the base 24. The upper mold 14 is attached to the upper mold holder 26. The upper mold holder 26 is supported by the guide rod 25 so as to be movable in the vertical direction. Further, the upper mold holder 26 is connected to a pressurizing device (not shown), and is driven by the pressurizing device to move in the vertical direction. The upper mold 14 attached to the upper mold holder 26 moves in the vertical direction between the molding position shown in FIG. 1 and the retracted position shown in FIG. 2 as the upper mold holder 26 moves up and down.

As shown in FIG. 1, the lower mold 13 and the upper mold 14 mold a molded product 31 having a predetermined shape, so that the protruding portion 33 of the lower mold 13 fits in the recess 32 of the upper mold 14. It is formed. The molded product 31 is molded into a predetermined shape using the metal plate material 12 (see FIG. 2) as a material.
The metal plate material 12 used in this embodiment is called a tailored blank, and as shown in FIG. 3, a first plate portion 34 made of a metal plate material having a relatively thin thickness and a first plate portion 34. It is formed by a second plate portion 35 made of a metal plate material having a relatively thick thickness. The first plate portion 34 and the second plate portion 35 are welded with their end faces abutting each other. In this embodiment, the upper surface of the metal plate material 12, that is, the surface in contact with the upper mold 14 at the time of molding is formed flat. A step 36 located at the boundary between the first plate portion 34 and the second plate portion 35 is formed on the lower surface of the metal plate member 12, that is, the surface in contact with the lower mold 13 during molding. The step 36 has a first step surface 37 formed of an end surface of the second plate portion 35.

As shown in FIG. 6, a molding surface 44 of the upper mold 14 is formed on the surface of the recess 32 of the upper mold 14. The molded surface 44 is formed in the same shape without unevenness in the front-rear direction of the upper mold 14.

As shown in FIG. 2, the lower mold 13 has a first molding surface 51 for molding the first plate portion 34 of the metal plate material 12 and a second molding for molding the second plate portion 35 of the metal plate material 12. It has a surface 52. The second molding surface 52 is separated from the molding surface 44 of the mold 14 above the first molding surface 51, and forms a step 53 together with the first molding surface 51. As shown in FIG. 4, the step 53 is formed so as to cross the lower mold 13 in the left-right direction. Further, as shown in FIG. 7, the step 53 includes a second step surface 54 that rises in the thickness direction of the metal plate member 12. FIG. 7 shows a state in which the metal plate material 12 is placed on the lower mold 13 and positioned at the molding position. The breaking position in FIG. 7 is the position shown by lines VII-VII in FIG.

The second stepped surface 54 rises from the second molded surface 52 in the thickness direction of the metal plate material 12 by a height corresponding to the difference between the thickness of the first plate portion 34 and the thickness of the second plate portion 35. The metal plate 12 is formed so as to be separated from the first stepped surface 37 by a predetermined distance to the front side when the metal plate 12 is positioned on the lower mold 13. Therefore, a space S for releasing the mold sandwiched between the first plate portion 34 and the second molding surface 52 is formed between the first step surface 37 and the second step surface 54. There is. In the following, a part of the first plate portion 34 exposed to the mold relief space S is referred to as a step portion 12a of the metal plate material 12.

The width of the space S for releasing the mold (distance between the first stepped surface 37 and the second stepped surface 54) is formed to be longer than the tolerance between the metal plate member 12 and the lower mold 13.
Since the space S for releasing the mold is formed in this way, the first stepped surface 37 of the metal plate material 12 may approach the second stepped surface 54 of the lower mold 13 within the tolerance. Even if there is, the distance between the first stepped surface 37 and the second stepped surface 54 does not become zero. Therefore, it is possible to prevent the relatively high first molding surface 51 of the lower mold 13 from overlapping with the relatively thick second plate portion 35 of the metal plate material 12 and causing molding defects during molding.

In the vicinity of the second molding surface 52 exposed to the mold relief space S, in other words, the step 53 between the first molding surface 51 and the second molding surface 52 of the second molding surface 52. , At least one spout 61 and at least one suction port 62 are open, respectively. As shown in FIG. 4, the spout 61 and the suction port 62 according to this embodiment are located at a plurality of positions arranged along a step 53 formed by the first molding surface 51 and the second molding surface 52, respectively. It is provided. The suction port 62 and the spout 61 according to this embodiment are arranged so as to be separated from each other in the left-right direction and the front-rear direction.

The lower mold 13 is provided with a refrigerant passage 63 for distributing the refrigerant and a refrigerant ejection passage 64 having one end connected to the refrigerant passage 63.
As shown in FIG. 8, the ejection port 61 is the other end of the refrigerant ejection path 64 formed for each ejection port 61. The refrigerant passage 63 for distribution has a refrigerant inlet 65 that opens on the lower surface of the lower mold 13, and one end of a supply pipe 20 (see FIG. 1) is connected to the refrigerant inlet 65 to be described later. Refrigerant is supplied from 22. FIG. 8 is a perspective view of the lower mold 13 cut along the line VIII-VIII in FIG. The refrigerant ejection path 64 extends linearly from the ejection port 61 into the lower mold 13. The other end of the refrigerant ejection path 64 is opened as an ejection port 61 on the second molding surface 52 in the vicinity of the step 53.

The refrigerant passage 63 is composed of a distribution section 66 provided at the same position in the front-rear direction as the refrigerant inlet 65, and a plurality of communication sections 67 extending forward from the distribution section 66. The distribution unit 66 extends from the refrigerant inlet 65 to a plurality of locations in the vertical direction and a plurality of locations in the left-right direction. The communication portion 67 is connected to each of a plurality of tip portions of the distribution portion. One end of the refrigerant ejection path 64 is connected to these communication portions 67.

Further, as shown in FIG. 9, the lower mold 13 is provided with a collecting passage 71 for collecting the refrigerant and a suction passage 72 having one end connected to the collecting passage 71.
The suction port 62 is the other end of the suction path 72 formed for each suction port 62. The collecting passage 71 has a refrigerant outlet 73 that opens to the lower surface of the lower mold 13, and one end of a suction pipe 21 (see FIG. 1) is connected to the refrigerant outlet 73 from a cooling unit 22 described later. Negative pressure is propagated. FIG. 9 is a perspective view of the lower mold 13 cut along the IX-IX line in FIG. The suction path 72 extends linearly from the suction port 62 into the lower mold 13.
The collecting passage 71 is formed in a T shape by a vertical passage 71a extending upward from the refrigerant outlet 73 and a horizontal passage 71b extending in the left-right direction from the upper end of the vertical passage 71a. The suction passage 72 is connected to the lateral passage 71b of the gathering passage 71.

These passages (refrigerant passage 63, refrigerant ejection passage 64, collecting passage 71, and suction passage 72) formed in the lower mold 13 are not shown in detail, but are drilled into the lower mold 13, respectively. It is formed by holes drilled in. The openings serving as the drill insertion ports of the refrigerant passage 63 and the collecting passage 71 are closed by plug members (not shown) except for the refrigerant inlet 65 and the refrigerant outlet 73. In this embodiment, the lower mold 13 corresponds to the "refrigerant-supplied mold" in the present invention.

As shown in FIG. 1, the cooling unit 22 includes first and second cooling devices 81 and 82, and a suction device 83.
The first cooling device 81 supplies the liquid refrigerant to the supply pipe 20 so that the refrigerant is ejected from the ejection port 61 at the time of molding. As the liquid refrigerant, water, a coolant containing a chemical, or the like can be used. The first cooling device 81 has a function of sending the refrigerant to the supply pipe 20 at the time of molding and a function of cooling the refrigerant to a predetermined temperature. In this embodiment, the first cooling device 81 corresponds to the "cooling device" in the present invention.

As shown in FIG. 2, the second cooling device 82 includes a circulation flow path 85 of the lower mold 13 including a heat exchange passage 84 in the lower mold 13, a feed side pipe 18 and a return side pipe 19, and an upper portion. It is connected to the circulation flow path 87 of the upper mold 14 including the heat exchange passage 86 in the mold 14 and the feed side pipe 16 and the return side pipe 17. As shown in FIGS. 8 and 9, the heat exchange passages 84 in the lower mold 13 include a refrigerant supply passage (refrigerant ejection passage 64 and a refrigerant passage 63) and a suction passage (suction passage 72 and an assembly passage). It is formed at a position separated from the 71) in the vertical direction and the horizontal direction.

The second cooling device 82 has a function of passing a refrigerant through the circulation flow path 85 of the lower mold 13 and the circulation flow path 87 of the upper mold 14, and a function of cooling the refrigerant to a predetermined temperature. There is. When the refrigerant of a predetermined temperature flows through the circulation flow path 85 of the lower mold 13, the lower mold 13 is cooled by the refrigerant. Further, when the refrigerant having a predetermined temperature flows through the circulation flow path 87 of the upper die 14, the upper die 14 is cooled by the refrigerant.
The suction device 83 sucks the refrigerant from the suction pipe 21 of the lower mold 13 and discharges it to a drainage tank (not shown).

In order to manufacture the molded product 31 from the metal plate material 12 using the hot press molding apparatus 11 configured in this way, first, the upper mold 14 is positioned at the retracted position as shown in FIG. 2, and the upper mold is placed. A metal plate material 12 heated to a predetermined temperature is inserted between the 14 and the lower mold 13. Then, as shown in FIG. 1, the upper mold 14 is lowered and the metal plate material 12 is molded by the upper mold 14 and the lower mold 13. At this time, since the lower mold 13 and the upper mold 14 are cooled by the refrigerant, the metal plate material 12 is rapidly cooled and hardened at the same time as molding. Further, at the time of this molding, in order for the first cooling device 81 to supply the refrigerant to the supply pipe 20, the refrigerant is ejected from the ejection port 61 of the lower mold 13. This refrigerant fills the mold relief space S and cools the step portion 12a of the metal plate material 12 exposed in the mold relief space S.

As a result, when the heated metal plate material 12 is press-molded, the step portion 12a of the metal plate material 12 is also hardened. Therefore, according to this embodiment, it is possible to provide a mold for hot press molding and a hot press molding apparatus in which the step portion 12a of the metal plate material 12 is also hardened to increase the hardness.
When a pair of molds 13 and 14 according to this embodiment were prototyped and tested, the results shown in FIG. 10 were obtained. The thickness of the first plate portion 34 of the metal plate material 12 used in this experiment is 1.2 mm, and the thickness of the second plate portion 35 is 1.6 mm. The hardness of the portion of the first plate portion 34 exposed to the mold relief space S was measured. The standard value of hardness is 400 Hv. The experiment was performed on two metal plate materials 12, and the hardness of each metal plate material 12 was measured at five locations in the longitudinal direction of the mold relief space S extending in the left-right direction of the mold.
According to this experiment, it can be seen that the hardness greatly exceeds the reference value and the hardness is stable for each metal plate material 12.

In this embodiment, a plurality of suction ports 62 are opened in the vicinity of the ejection port 61 (the opening at the other end of the refrigerant ejection path 64). Therefore, the refrigerant that has hit the first plate portion 34 and returned in the mold escape space S, that is, the refrigerant whose temperature has risen, can be sucked out from the suction port 62. Therefore, since the first plate portion 34 can always be cooled with a low-temperature refrigerant, the cooling efficiency is high and quenching can be sufficiently performed.

The spout 61 and the suction port 62 according to this embodiment are provided at a plurality of positions arranged along a step 53 formed by the first molding surface 51 and the second molding surface 52, respectively. Therefore, since the refrigerant can be supplied to the entire area of the mold relief space S, quenching can be evenly applied to the entire area of the step portion 12a of the metal plate material 12, and a high-quality molded product 31 is molded. be able to.

(Second Embodiment)
The first molding surface 51 and the second molding surface 52 of the lower mold 13 can be formed as shown in FIGS. 11 to 13. In these figures, the same or equivalent members as those described with reference to FIGS. 1 to 9 are designated by the same reference numerals, and detailed description thereof will be omitted as appropriate.
A large number of spouts 61 and a large number of suction ports 62 are formed on the first molding surface 51 and the second molding surface 52 of the lower mold 13 shown in FIG. 11, respectively. The spout 61 and the suction port 62 shown in FIG. 11 are provided so as to be separated from each other at positions separated from each other at predetermined intervals in the front-rear direction of the lower mold, and the first molding surface 51 and the second molding surface 51 and the second molding It is provided in the entire area of the surface 52. In addition to providing the spout 61 and the suction port 62 in the entire area of the first molding surface 51 and the second molding surface 52 in this way, the first molding surface 51 and the second molding surface 52 are particularly cooled. It can be formed only in the site where the sex is enhanced. That is, the spout 61 and the suction port 62 are formed on at least a part of the first molding surface 51 and the second molding surface 52.

These ejection ports 61 are formed at the other end of a refrigerant ejection path (not shown) equivalent to the refrigerant ejection path 64 shown in FIG. The refrigerant ejection passages are provided so as to line up in the front-rear direction at the formation pitch of the ejection port 61 in the front-rear direction of the lower mold 13. These refrigerant ejection passages are connected to a communication passage (not shown) having a shape in which the communication portion 67 shown in FIG. 8 is extended in the front-rear direction. Further, these communication passages are connected to two refrigerant inlets 65 on the lower surface of the lower mold 13 by a distribution passage (not shown) having the same shape as the distribution portion 66 shown in FIG. The two refrigerant inlets 65 are each connected to the first cooling device 81 (see FIG. 2) by a supply pipe 20. Of the two refrigerant inlets 65, the refrigerant inlet 65 located on the front side of the lower mold 13 is connected to a large number of ejection ports 61 provided in the front half of the lower mold 13. The refrigerant inlet 65 located on the rear side of the lower mold 13 is connected to a large number of ejection ports 61 provided in the rear half of the lower mold 13.

The plurality of suction ports 62 are formed at the other end of a suction path (not shown) equivalent to the suction path 72 shown in FIG. The suction passages are provided so as to line up in the front-rear direction at the formation pitch of the suction port 62 in the front-rear direction of the lower mold 13. These suction passages are connected to a plurality of communication passages extending in the front-rear direction of the lower mold 13. These plurality of communication passages are connected to the refrigerant outlet 73 on the lower surface of the lower mold 13 by a collection passage (not shown) equivalent to the collection passage 71 shown in FIG. The refrigerant outlet 73 is connected to the suction device 83 (see FIG. 2) by a suction pipe 21.

The first molding surface 51 and the second molding surface 52 shown in FIG. 11 are formed by a large number of convex portions 91 as shown in FIG. 12 when enlarged. These convex portions 91 are formed in a columnar or truncated cone shape. The circular tip surface of the convex portion 91 substantially functions as a first molding surface 51 and a second molding surface 52. A plane 92 along the first and second molding surfaces 51 and 52 is formed between these convex portions 91. The flat surface 92 is separated from the metal plate material 12 at the time of molding. Therefore, in the lower mold 13, a gap is formed between the metal plate member 12 and the flat surface 92 at the time of molding. Refrigerant is supplied to this gap from the ejection port 61 at the time of molding. This refrigerant spreads widely on the lower surface of the metal plate material 12 to cool the metal plate material 12. The refrigerant whose temperature has risen by taking heat from the metal plate material 12 is sucked into the suction port 62 and discharged from the lower mold 13.

Therefore, a large amount of refrigerant supplied to the mold release space S is discharged from the mold release space S to the first molding surface 51 side and the second molding surface 52 side without stagnation. As a result, the space S for releasing the mold is always filled with the low-temperature refrigerant, and the cooling efficiency is improved. On the other hand, when the amount of the refrigerant supplied to the mold release space S is smaller than that of the surroundings, the mold release space S is provided from the first molding surface 51 side and the second molding surface 52 side. The refrigerant is replenished to the space S, and the amount of the refrigerant supplied to the mold relief space S can be increased.
By improving the efficiency of cooling by the refrigerant and increasing the amount of the refrigerant in this way, quenching of the step portion 12a of the metal plate material 12 becomes more reliable.

When a large number of convex portions 91 are formed on the first molding surface 51 and the second molding surface 52, nozzles 101 are provided in the refrigerant ejection passages 64 connected to the ejection port 61, respectively, as shown in FIG. Can be done. FIG. 13 shows an example in which the nozzle 101 is attached to the refrigerant ejection path 64 that opens in the mold escape space S. However, the nozzle 101 can be attached to all the refrigerant ejection passages 64 of the lower mold 13.

The downstream portion (the other end side) including the ejection port 61 of the refrigerant ejection passage 64 shown in FIG. 13 is formed by the screw holes 102.
The nozzle 101 has an ejection passage 103 from which the refrigerant is ejected, and is screwed into the screw hole 102. The ejection passage 103 has three functional parts. The first functional portion is a tapered portion 104 that constitutes an upstream end portion of the ejection passage 103. The tapered portion 104 is formed in a tapered shape in which the hole diameter gradually decreases toward the downstream side from the opening 105 located at the upstream end of the nozzle 101. The opening 105 at the upstream end of the nozzle 101 is larger than the inner diameter of the refrigerant ejection path 64 connected to the screw hole 102.

The second functional unit is a passage hole 106 located at the center of the nozzle 101 in the axial direction. The passage hole 106 connects the downstream end of the tapered portion 104 with the hexagonal hole 107, which is a third functional portion described later. The hole shape of the passage hole 106 is circular. The hole diameter of the passage hole 106 is constant from the upstream end to the downstream end. This pore size is related to the amount of refrigerant passing through the nozzle 101. As the hole diameter of the passage hole 106 increases, the amount of refrigerant passing through the nozzle 101 increases. On the other hand, if the hole diameter of the passage hole 106 becomes smaller, the amount of the refrigerant passing through the nozzle 101 decreases.

The length of the passage hole 106 needs to be a certain length in order to obtain the action of adjusting the flow direction of the refrigerant. The length of the passage hole 106 according to this embodiment is the same as the hole diameter. The length of the passage hole 106 may be longer than the hole diameter. The length of the passage hole 106 according to this embodiment is shorter than the length of the tapered portion 104 in the axial direction.
When this embodiment is adopted, a plurality of types of nozzles 101 having different hole diameters of the passage holes 106 are formed in advance. These nozzles 101 are selected to have a hole diameter such that the amount of refrigerant ejected from the refrigerant ejection path 64 is a target amount, and are attached to the refrigerant ejection path 64.

The third functional part is a hexagonal hole 107 which is an opening on the downstream side of the ejection passage 103. The hexagonal hole 107 is formed in a shape into which a hexagonal wrench (not shown) is fitted. The work of screwing the nozzle 101 into the screw hole 102 and the work of removing the nozzle 101 from the screw hole 102 are performed by turning a hexagon wrench fitted in the hexagonal hole 107.
..

According to this embodiment, by attaching the nozzle 101 to which the flow rate of the refrigerant is relatively large to the ejection port 61 for ejecting the refrigerant into the space S for releasing the mold, the stepped portion 12a of the metal plate material 12 is further increased. It becomes possible to cool efficiently.

In the above-described embodiment, an example in which the ejection port 61 is formed in the lower mold 13 is shown. However, the present invention is not bound by such limitations. When the step 36 is formed on the upper surface of the metal plate material 12, the spout 61 is formed on the upper die 14. Further, when the step 36 is formed on the upper surface and the lower surface of the metal plate material 12, the spout 61 is formed on the upper die 14 and the lower die 13, respectively.
Further, in the above-described embodiment, an example in which a plurality of suction ports 62 are provided is shown. However, the suction port 62 may not be provided, or only one may be provided at a position corresponding to the space S for releasing the mold.

In the above-described embodiment, an example is shown in which the step 36 of the metal plate material 12 is formed on the lower mold 13 side. However, the present invention is not limited to such a limitation, and can be carried out even when the step 36 of the metal plate material 12 is formed on the upper mold 14 side. In this case, a step 53 is formed in the upper mold 14 so that a space S for releasing the mold is formed between the upper mold 14 and the metal plate material 12, and the spout 61 and the suction port 62 are formed. It is formed.

Further, in the above-described embodiment, an example is shown in which the cross-sectional shape of the molded product 31 is a so-called hat shape. However, the present invention is not limited to such a limitation, and can be applied to a mold for molding a molded product having another shape.

11 ... Hot press molding device, 13 ... Lower mold, 14 ... Upper mold, 51 ... First molding surface, 52 ... Second molding surface, 53 ... Step, 61 ... Spout, 62 ... Suction port, 63 ... Refrigerant passage, 64 ... Refrigerant ejection path, 81 ... First cooling device (cooling device), 83 ... Suction device, 91 ... Convex portion.

Claims (5)

A mold used for press molding of heated metal plates.
Refrigerant passage through which refrigerant flows and
At least one refrigerant ejection path, one end of which is connected to the refrigerant passage and the other end of which opens into the molding surface of the mold.
The first molding surface and
The first molding surface is separated from the molding surface of another mold, and is provided with a second molding surface that forms a step together with the first molding surface.
A mold characterized in that the other end of the at least one refrigerant ejection path is opened in the vicinity of a step between the first molding surface and the second molding surface of the second molding surface. .. In the mold according to claim 1,
A mold characterized in that at least one suction port into which a refrigerant is sucked is opened in the vicinity of the other end of the refrigerant ejection path. In the mold according to claim 1 or 2.
A mold characterized in that the opening at the other end of the refrigerant ejection path and the suction port are provided at a plurality of positions arranged along the step. In the mold according to claim 3,
At least a part of the second molding surface is formed by a large number of protrusions.
A gold having a plurality of protrusions formed on the second molding surface is formed with an opening at the other end of the plurality of refrigerant ejection passages and a plurality of suction ports. Type. A pair of dies for press-molding heated metal plates,
A cooling device for supplying a refrigerant to at least one of the pair of molds is provided.
The mold to which the refrigerant is supplied is
The mold according to any one of claims 1 to 4.
A hot press molding apparatus characterized in that a refrigerant is supplied from the cooling device to the refrigerant passage.

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