JP2006264163A - Vacuum forming mold and its manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vacuum forming mold having many evacuation passages or having many evacuation passages and passages for cooling that are manufacturable inexpensively and in a short time, and its manufacturing method. <P>SOLUTION: The vacuum forming mold 1 is formed by laminating, jointing and processing a plurality of metal sheets 2. It is comprised and composed of a plurality of the metal sheets 2 that are laminated and form the cavity 3 and the evacuation passages 6 that are formed of the gaps of the jointing faces between the metal sheet 2 and the metal sheet 2 forming the cavity 3. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention particularly relates to a female mold and a manufacturing method thereof among vacuum forming molds and a manufacturing method thereof.

  Today, vacuum molding dies are widely used in the manufacture of various packaging materials and containers, as well as bathtubs and leisure pools. The vacuum forming mold has the characteristics that the force applied to the mold is small and the cost required for manufacturing is low. In vacuum forming, a vacuum suction channel (exhaust hole) is formed in a female mold having a cavity, and a molded sheet made of thermoplastic resin or the like is sucked into and closely adhered to the cavity through the vacuum suction channel to form a molded product. To do. Also, by coordinating the female mold having the cavity and the male mold having the plug, the molded sheet is sucked to the female mold side through the vacuum suction flow path provided in the female mold, and the male mold is pressed in the female mold side direction. There is also a method of forming a molded product by sucking and closely adhering the molded sheet to the cavity.

  As described above, in vacuum formation, the vacuum suction flow path provided in the female mold is a very important element in forming a molded product, and conventionally it is common to form holes by drilling or electric discharge machining. It was the target. However, if the hole is too large, the molded sheet (resin) flows into the hole and a protrusion is generated. In addition, when there are few holes that are flow paths for vacuum suction, air remains in the mold and a molded product with an accurate shape cannot be obtained, and the molding cycle becomes long. For this reason, various devices have been devised for the method of forming the flow path for vacuum suction provided in the female mold.

  For example, after adhering many synthetic resin fillers upright on the surface of a female mold having the same shape as the product to be molded, a metal plating layer is formed on the surface of the female mold, and then with a solvent. A technique for forming a large number of fine air holes by elution of the filler remaining in the metal plating layer is disclosed (for example, see Patent Document 1). Also disclosed is a method of securing a large number of channels for vacuum suction by forming a mold with a neutral fiber board having air permeability obtained by hot-pressing wood fibers together with an adhesive (see, for example, Patent Document 2). ).

In general, a vacuum forming mold is provided with a cooling flow path for cooling the mold, and cooling water is passed through the cooling mold to cool the cavity, thereby shortening the molding cycle time. If the cooling channel is not properly formed, the molded product is deformed or the molding cycle time is increased. Therefore, a technology is disclosed in which a cooling plate is provided on the lower surface of the female mold, a knockout plate is provided, a dovetail-shaped pipe mounting groove is cut from the lower surface side of the knockout plate along the cavity, and a cooling pipe is provided on this. (For example, refer to Patent Document 3).
JP 2002-86552 A JP 2001-301019 A JP-A-6-47804

  The method of forming a hole in a female die by drilling or electric discharge machining requires a very long time for processing and increases the manufacturing cost of the mold. The technique described in Patent Document 1 can form a large number of fine air holes. However, many processes are required to form the air holes, and much time is required to manufacture the mold. Since the technique described in Patent Document 2 is a method of securing a large number of vacuum suction channels by forming a mold with a neutral fiber board, particularly when used for a mold of a large molded product, The mold itself may be deformed due to insufficient strength.

  In addition, the vacuum forming mold needs to be provided with a cooling flow path as well as a number of vacuum suction flow paths. However, a method of forming holes by drilling or electric discharge machining, Patent Document 1 and Patent Document 2 The described technique does not disclose a technique for providing a complicated cooling flow path or a fine cooling flow path along the cavity. Providing a cooling flow path in the vacuum forming dies described in Patent Document 1 and Patent Document 2 is not easy in terms of processing and sealing properties. On the other hand, although the technique described in Patent Document 3 forms a cooling channel, the cooling channel cannot be easily formed when the cavity has a complicated shape.

  An object of the present invention is to provide a vacuum forming metal having a large number of vacuum suction flow paths that can be manufactured inexpensively and in a short time, or having a large number of vacuum suction flow paths and cooling flow paths. It is to provide a mold and a manufacturing method thereof.

The present invention is a vacuum forming mold for laminating, joining and processing a plurality of metal plates,
A plurality of stacked metal plates forming a cavity;
A vacuum forming die comprising a metal plate forming a cavity and a vacuum suction flow path formed by a gap between the joining surfaces of the metal plates.

Further, the present invention is a vacuum forming mold for forming by laminating, joining and processing a plurality of metal plates,
A plurality of stacked metal plates forming a cavity;
A plate-like body and / or a rod-like body sandwiched between the metal plate forming the cavity and the metal plate,
A vacuum molding die comprising: a metal plate joined with the plate-like body and / or the rod-like body sandwiched therebetween, and a vacuum suction channel formed between the metal plate and the metal plate. is there.

Further, the present invention is a vacuum forming mold for forming by laminating, joining and processing a plurality of metal plates,
A plurality of stacked metal plates forming a cavity;
A groove is provided in at least a part of the metal plate forming the cavity, the metal plate provided with the groove and the metal plate are joined, and a vacuum suction flow path formed on a joint surface between the metal plate and the metal plate; And a vacuum forming die characterized by including.

  Moreover, this invention is further equipped with the cooling flow path inside, The vacuum molding die of any one of Claim 1 to 3 characterized by the above-mentioned.

  Further, in the present invention, the cooling flow path is provided so as to extend along the cavity.

The present invention also includes a step of creating slice data from three-dimensional CAD data;
Processing a plurality of metal plates into a predetermined shape based on the three-dimensional CAD data;
Laminating the processed metal plate at a predetermined position, joining the metal plate using a joining means, and forming a joined body;
Processing the joined body to form a cavity;
The at least part of the joining of the metal plates performed using the joining means is a local joining, leaving a gap serving as a vacuum suction channel between the metal plates. It is a manufacturing method.

Further, the present invention is a method of manufacturing a vacuum molding die provided with a cooling channel inside,
Creating slice data from 3D CAD data;
Processing a plurality of metal plates into a predetermined shape based on the three-dimensional CAD data;
Laminating the processed metal plate at a predetermined position, and joining the metal plate using a joining means to form a joined body;
Processing the joined body to form a cavity, and
Of the joining of the metal plates performed using the joining means, the part forming the cooling channel is joined to the entire circumference of the cooling channel, and at least a part of the other part is locally joined. A method for manufacturing a vacuum forming mold is characterized in that a gap is formed between the metal plates as a vacuum suction flow path.

  In the present invention, the joining means is an adhesive, and the manufacturing method of a vacuum forming mold according to claim 6 or 7.

  According to the present invention, a vacuum forming mold is formed by laminating, joining and processing a plurality of metal plates, and a plurality of metal plates laminated to form a cavity, and joining of the metal plate and the metal plate And a vacuum suction flow path formed by a gap between the surfaces, it is possible to perform vacuum suction through the gap between the metal plates, and it is necessary to separately provide a suction hole as in a conventional vacuum forming mold. Absent. As a result, the mold can be manufactured inexpensively and in a short time.

  Further, since the vacuum suction channel is a gap between the joint surfaces of the metal plate and the metal plate, the clearance is sufficiently small and does not affect the molding surface. Further, since the vacuum suction channel is a gap between the joining surfaces of the metal plate and the metal plate, many vacuum suction channels can be formed.

  Further, according to the present invention, the vacuum suction flow path formed between the metal plates is formed by sandwiching the plate-like body and / or the rod-like body between the metal plates. Alternatively, the width (thickness) of the vacuum suction channel can be easily adjusted by changing the thickness of the rod-shaped body. The number of vacuum suction channels can also be arbitrarily adjusted.

  According to the invention, the vacuum suction channel formed between the metal plates is provided with a groove in at least a part of the metal plate, and the metal plate and the metal plate are joined to each other by joining the metal plate and the metal plate. Since the vacuum suction flow path is formed on the joint surface with the metal plate, the width (thickness) of the vacuum suction flow path can be easily adjusted by changing the size of the groove. The number of vacuum suction channels can also be arbitrarily adjusted.

  Further, according to the present invention, since the cooling channel is further provided inside, the cavity can be efficiently cooled, and the molding cycle time can be shortened. Further, since the present vacuum forming mold is a mold formed by laminating metal plates, it can be easily formed even with a cooling channel having a complicated shape or a fine shape.

  According to the present invention, the cooling channel is provided along the cavity, so that the cooling efficiency is further increased. Further, the temperature can be easily adjusted, and deformation of the molded product can be prevented.

  According to the present invention, the step of creating slice data from the three-dimensional CAD data, the step of processing a plurality of metal plates into a predetermined shape based on the three-dimensional CAD data, and the processed metal plates at predetermined positions. Laminating and joining a metal plate using a joining means to form a joined body; and processing the joined body to form a cavity, and at least one of joining of the metal plates performed using the joining means Since the joining of the parts is local joining, a vacuum forming mold having a vacuum suction flow path can be easily manufactured.

  According to the present invention, the step of creating slice data from the three-dimensional CAD data, the step of processing a plurality of metal plates into a predetermined shape based on the three-dimensional CAD data, and the processed metal plates at predetermined positions. Laminating and joining a metal plate using a joining means to form a joined body, and processing the joined body to form a cavity, and cooling of the joining of the metal plates performed using the joining means Since the entire circumference of the cooling channel is joined to the part forming the working channel and at least a part of the other part is joined locally, the cooling channel and the vacuum suction are easily It is possible to manufacture a vacuum forming mold having the flow paths.

  Further, according to the present invention, since the metal plate is joined by an adhesive, the joining operation is simple and can be performed in a short time. In addition, the metal plates can be joined at low cost.

  FIG. 1 is a view showing a part of a cross-sectional view of a female mold 1 which is a vacuum forming mold as a first embodiment of the present invention. FIG. 2 is an enlarged view showing a part of the II part of FIG. 1, and is a view showing a vacuum suction flow path formed between metal plates. FIG. 2 is a view for explaining a vacuum suction channel formed between metal plates, and is not drawn to the same scale.

  The female die 1 is formed by laminating, joining and processing a plurality of metal plates 2. The female mold 1 has a cavity 3 on the upper surface, and a cooling flow path 4 (4a, 4b, 4c, 4d, 4e, 4f, 4g, 4h, 4i, 4i, 4j, 4k) along the cavity 3 inside the mold. ). Further, since the metal plate 2a and the metal plate 2b or the metal plate 2b and the metal plate 2c are locally joined by the adhesive 5 (5a, 5b, 5c, 5d, 5e), a gap remains between the metal plates. It becomes the flow path 6 (6a, 6b) for vacuum suction.

  The female mold 1 is formed by using a vacuum suction device (not shown) from the lower surface 8 of the female mold 2 by placing a molded sheet such as a heated thermoplastic resin with a clamp and placing it on the upper part 7 of the female mold 1. Is formed in the cavity 3 by vacuum suction. Although only the female die 1 is shown in the embodiment of the present invention, the vacuum forming die may be composed of the female die 1 having the cavity 3 and the male die having a plug (not shown). Of course it is good.

  The metal plate 2 can use an aluminum alloy or a zinc alloy. This is because in vacuum molding, the force applied to the mold is small compared to a mold for injection molding and the temperature applied to the mold is relatively low. However, the material of the metal plate 2 is not particularly limited to these, and the material to be used can be selected according to the requirements of the mold, such as ease of processing, strength, or cost. For example, a stainless material can be used in an area where strength is required. Further, although the entire mold 1 can be made of a metal plate made of the same material, it goes without saying that metal plates made of different materials can be used.

  The thickness of the metal plate 2 to be used can be arbitrarily set and does not necessarily have to be the same thickness. In the embodiment of the present invention, the metal plate 2 forms the cavity 3 and the flow path 6 for vacuum suction. For this reason, the thickness of the metal plate 2 can be determined in consideration of the number of necessary vacuum suction flow paths 6. For example, a thick metal plate is used in a place where the number of vacuum suction flow paths 6 may be small, and a thin metal plate is used in a place where the number of vacuum suction flow paths 6 is large.

  The thickness of the metal plate 2 is desirably determined in consideration of the shape of the cooling flow path 4 or the shape of the cavity 3. As shown in FIG. 1, the cooling channel 4 is formed by cutting a portion corresponding to the cooling channel in the metal plate 2 with a laser or the like and laminating the metal plates 2. If the width of the path 4 is set to the thickness of the metal plate 2, the processing becomes easy. Moreover, as shown in FIG. 1, if the thin metal plate 2 is used for the corner | angular part 9 (9a, 9b) of the cavity 3, a processing amount will decrease. On the other hand, for the region 10 where the cavity 3 is not formed, it is possible to use, for example, a thick metal plate so that the mold manufacturing time is minimized.

  The cooling flow path 4 has a great influence on the molding cycle time. Further, if the cavity 3 is not properly cooled, warpage occurs in the molded product. For this reason, it is necessary to provide the cooling flow path 4 at an appropriate position. In the conventional mold, since the cooling flow path is formed using a drill or the like, it is difficult to form the cooling flow path having a complicated shape along the cavity 3. However, in the present invention, the metal plates are processed and laminated to form a mold, so that even if the cooling flow path 4 has a complicated shape, the processing of each metal plate 2 is not possible. It is easy and the mold 1 can be manufactured in a short time. If a thin metal plate is used, a very fine flow path can be provided. As a result, the cavity 3 can be efficiently cooled, and the molding cycle time can be shortened.

  In the embodiment of the present invention, since the cooling flow path 4 is provided along the cavity, the cooling efficiency is very high. However, the cooling flow path 4 does not necessarily have to be provided along the cavity 3 or to enclose the entire cavity. For example, when the temperature of a specific location of the cavity 3 is predicted to increase locally from the shape of the cavity 3, the cooling flow path 4 is provided in the mold 1 near the portion where the temperature is predicted to increase. You can also. As a result, the temperature distribution of the cavity 3 can be made uniform, and a highly accurate molded product without warping can be formed. Thus, the cooling flow path 4 may be provided in accordance with the purpose of use of the mold 1 or the like.

  An adhesive 5 can be used for joining the metal plates 2. The vacuum molding die 1 has a smaller force applied to the mold than a mold for injection molding and the temperature applied to the mold is relatively low. As the adhesive 5, a thermosetting resin adhesive or a composite adhesive generally used for bonding metal plates can be used. Specifically, polyamide resin, epoxy resin, polyimide resin, cyanoacrylate, modified acrylic resin, epoxy / phenol resin, and the like can be used. Thus, since the adhesive 5 can be used for joining the metal plates 2, the joining operation is simple and a mold can be manufactured at low cost.

  In addition to the adhesive 5, the metal plate 2 can be joined by welding such as spot welding or seam welding, joining by brazing copper wax, silver wax, etc., joining using solder, and diffusion joining with strong joining force. It is also possible to use it. It is necessary to join the entire circumference of the cooling flow path 4 so that the cooling fluid does not leak. In this case, if the bonding force between the metal plates is weak, the cooling fluid leaks from the flow path. For example, the metal plate 2 having the cooling flow path 4 is bonded by diffusion bonding, and the bonding of other metal plates is bonded. Agent 5 can also be used. Of course, the method for joining the metal plates forming one mold may not be one kind, and two or more kinds of joining methods may be used.

  The vacuum suction flow path 6 can be formed in the following manner. By locally joining the metal plate 2 with the adhesive 5, a gap communicating from the cavity 3 to the lower surface 8 is left between the metal plates, and this is used as a flow path 6 for vacuum suction. Therefore, the clearance δ of the vacuum suction flow path 6 in this embodiment is very narrow. 3 (a), 3 (b), and 3 (c), the adhesive 5 is locally applied to the metal plate 2 for forming the vacuum suction flow path 6 between the metal plates. It is a figure which shows a state. FIG. 3A, FIG. 3B, and FIG. 3C are views of a single metal plate viewed from the front.

  In FIG. 3A, adhesives 5 f and 5 g are continuously applied from both the cavity surface 3 to the lower surface 8 on both sides of the metal plate 2. Thereby, even if the mold 1 is vacuum-sucked, the atmosphere is not sucked from both sides of the metal plate 2. Further, as shown in FIG. 3A, the adhesives 5 h, 5 i, 5 j, 5 k, 5 l, and 5 m are spot-coated on the metal plate 2. As a result, a vacuum suction flow path 6 extending from the cavity surface 3 to the lower surface 8 as shown by the arrow in FIG.

  Similarly, in FIG. 3B, adhesives 5 f and 5 g are continuously applied from both the cavity surface 3 to the lower surface 8 on both sides of the metal plate 2. Thereby, even if the mold 1 is vacuum-sucked, the atmosphere is not sucked from both sides of the metal plate 2. Further, as shown in FIG. 3B, the adhesives 5n, 5o, 5p, and 5q are coated on the metal plate 2 in an island shape. As a result, a vacuum suction flow path 6 extending from the cavity surface 3 to the lower surface 8 as shown by the arrow in FIG. 3B is formed.

  Further, also in FIG. 3C, adhesives 5f and 5g are continuously applied to both sides of the metal plate 2 from the cavity surface 3 to the lower surface 8 in order to prevent air suction from both sides of the metal plate 2. Has been. Moreover, as shown in FIG.3 (c), the rod-shaped adhesives 5r and 5s which continued from the cavity 3 surface to the lower surface 8 are apply | coated to the metal plate. As a result, a vacuum suction flow path 6 that leads from the cavity surface 3 to the lower surface 8 indicated by the arrow in FIG.

  As described above, the adhesive 5 is applied to both sides of the metal plate 2 so that air is not sucked from the side surfaces, and the adhesive 5 is locally applied to bond the metal plates 2 together, thereby A vacuum suction channel 6 leading from the surface 3 to the lower surface 8 can be formed. Needless to say, the arrangement of the adhesive 5 is not limited to FIGS. 3A, 3B, and 3C. However, even when the adhesive 5 is applied locally, if the adhesive 5 is applied continuously to both side surfaces (both ends) of the metal plate, it can be used for vacuum suction leading from the cavity surface 3 to the lower surface 8. Needless to say, the flow path 6 cannot be formed.

  4 (a) and 4 (b) are diagrams showing a local adhesive application method in which the vacuum suction flow path 6 cannot be formed. In the arrangement of the adhesive 5 as shown in FIG. 4A or FIG. 4B, even if the adhesive 5 is applied locally, a flow for vacuum suction that leads from the cavity surface 3 to the lower surface 8 is achieved. Of course, the path 6 cannot be formed. In FIG. 4A, adhesives 5f and 5g are continuously applied to both sides of the metal plate 2 from the cavity surface 3 to the lower surface 8 in order to prevent air suction from both sides of the metal plate 2. ing. In addition, since the adhesives 5t, 5u, and 5v that are continuous to the adhesives 5f and 5g applied to both sides of the metal plate 2 are provided, the vacuum suction flow path 6 that leads from the cavity surface 3 to the lower surface 8 is not formed. . Similarly, in FIG. 4B, since the adhesive 5 is applied so as to surround the periphery of the metal plate, the vacuum suction flow path 6 leading from the cavity surface 3 to the lower surface 8 is not formed in this case as well.

  In this embodiment, since an example of suction from the lower surface 8 side of the mold 1 is shown, as shown in FIGS. 3 (a), 3 (b), and 3 (c), both side surfaces of the metal plate The adhesive 5 is continuously applied from both the cavity surface 3 to the lower surface 8 on both sides of the metal plate 2 so that air is not sucked from the air. However, in the case where a vacuum suction chamber is provided so as to wrap the entire mold, it is a matter of course that it is not always necessary to close both sides of the metal plate with an adhesive. In short, in order to make the cavity surface vacuum (reduced pressure), it is only necessary to prevent air from leaking from unnecessary places and to leave a vacuum suction gap between the metal plates. .

  The vacuum suction flow path 6 is not necessarily provided between all the metal plates. It may be determined in consideration of the shape of the cavity 3 or the like. For example, it is of course possible to provide the vacuum suction flow path 6 for every several metal plates. Although an example in which the flow path 6 for vacuum suction is formed using the adhesive 5 is shown here, a foil may be used instead of the adhesive 5. Further, when a vacuum suction chamber is provided so as to wrap the entire mold 1, it is possible to use a method of locally welding the periphery of the laminated metal plates.

  As described above, the flow path for vacuum suction can be formed by locally joining the metal plates, so that it is not necessary to provide a separate hole as in the prior art. Further, since the gap between the metal plates is used as the vacuum suction flow path 6, the gap is sufficiently small so that the molded sheet does not enter the vacuum suction flow path 6 and does not affect the molding surface. Further, since the vacuum suction flow path 6 is a gap between the joining surfaces of the metal plate and the metal plate, many vacuum suction flow paths can be formed. Therefore, the mold 1 can be manufactured in a short time and at a low cost. It should be noted that the region 10 where the cavity 3 is not formed as shown in FIG. 1 and the portion where the vacuum suction flow path 6 does not need to be formed needs to be bonded so that the atmosphere is not sucked. .

  In the embodiment of the present invention, an example has been shown in which the adhesive 5 is locally disposed on the metal plate 2 to leave a gap between the metal plates to be used as the vacuum suction flow path 6. It is also possible to form the vacuum suction flow path 6 by this method.

  FIG. 5 is a diagram showing another embodiment of a method for forming a vacuum suction flow path. A thin metal plate 11 (11a, 11b) is fixed to the metal plate 2. Another metal plate is further laminated on the metal plate 2, and the other metal plate 2 and the plate-like body 11 are joined, so that the vacuum suction having the thickness of the plate-like body 11 around the plate-like body 11 is achieved. Can be formed. By this method, a vacuum suction channel having an arbitrary size can be easily provided. In addition, you may use a rod-shaped body with a small diameter instead of a plate-shaped body, or a plate-shaped body and a rod-shaped body simultaneously. Further, since the number of plate-like bodies is not limited, any number of vacuum suction channels can be formed.

  FIG. 6 is a diagram showing still another embodiment of a method for forming a flow path for vacuum suction. A groove 12 that communicates from the cavity 3 to the lower surface 8 is provided in the metal plate 2. By stacking another metal plate on the metal plate 2 and joining the metal plate 2 and the other metal plate so that the groove 12 is not blocked, a vacuum having a cross-sectional area of the groove 12 between the metal plates. A suction channel can be formed. By this method, a vacuum suction channel having an arbitrary size can be easily provided. Of course, the number of grooves is not limited to one.

  FIG. 7 is a view showing a part of a cross-sectional view of a female die 20 which is a vacuum forming die as a second embodiment of the present invention. FIG. 8 is a view showing a part of a cross-sectional view of a female die 30 which is a vacuum forming die as a third embodiment of the present invention. The parts corresponding to the mold 1 in FIG. FIG. 7 has metal blocks 21 a and 21 b on both sides of the mold 20, unlike the mold 1 of FIG. 1. In this embodiment, the cavity 20 is not formed at both ends of the mold 20, and it is not necessary to provide the vacuum suction flow path 6, so a metal block is used instead of the metal plate 2. Thus, it is not necessary to form all the metal mold | die 20 with the metal plate 2, and it can also use the metal blocks 21a and 21b as needed. Thereby, the processing time of the whole mold 1 is shortened, and the manufacturing cost can be reduced.

  In FIG. 8, unlike the mold 1 of FIG. 1, metal plates 31 a and 31 b are laminated and bonded on both sides of the mold 30 in parallel with the lower surface 8 of the mold 30. Thus, the mold 30 does not have to be formed by laminating and joining all the metal plates at right angles to the lower surface 8 of the mold 30, and the metal plates are partially molded in consideration of processing time or manufacturing cost. It can also be formed by being laminated and bonded in parallel to the lower surface 8 of 30.

FIG. 9 is a view showing a part of a cross-sectional view of a female die 40 which is a vacuum forming die as a fourth embodiment of the present invention. The parts corresponding to the mold 1 in FIG.
The metal mold (female mold) 40 includes a plurality of metal plates 2 stacked in the horizontal direction, and metal plates (metal blocks) 41 and 42 having thick bottom portions. As in the mold 1 shown in FIG. 1, a vacuum suction flow path is provided between the metal plates 2 forming the cavities 3. Further, a vacuum suction channel (hole) 43 (43a, 43b, 43c, 43d) is also formed in the thick metal plates (metal blocks) 41, 42 at the bottom. A vacuum suction chamber 44 is fixed around the mold 40, and a vacuum suction device (not shown) is connected to the chamber 44 for use.

  A mold (female mold) 40 shown in FIG. 9 is different from the mold 1 shown in FIG. 1 in that the outer peripheral surface 45 of the mold has a complicated shape. This is due to the difference in the mold manufacturing method. In the mold 1 shown in FIG. 1, a plurality of rectangular metal plates 2 having the same size are used to process only a reference hole (not shown) and a cooling channel 4 necessary for stacking. The outer peripheral surface of the mold 1 is rectangular in a sectional view because it is drilled, laminated, and joined. On the other hand, in the mold 40 shown in FIG. 9, the metal plate is processed (cut) not only in the part forming the cavity, but also in the part forming the outer peripheral surface of the mold, and this is laminated and bonded. The outer peripheral surface 45 of the mold has a complicated shape.

  In the mold 1 shown in FIG. 1, a plurality of rectangular metal plates 2 having the same size are stacked and joined to obtain a joined body, and then the rectangular parallelepiped joined body is formed on the cavity surface 3 based on the three-dimensional CAD data. Can be formed by processing. Since rectangular metal plates 2 having the same size are laminated and joined, the amount of processing before lamination is small, and accordingly, deformation and distortion of the metal plates are also suppressed. For this reason, it is not necessary to repair the deformation of the metal plate or the like, and the metal plates having the same shape are stacked and joined, so that these operations can be easily performed. This manufacturing method is particularly effective in, for example, a mold for injection molding in which a large load is applied to the mold.

  On the other hand, as in the case of the mold 40 shown in FIG. 9, when the metal plate 2 that has been processed not only in the vicinity of the cavity but also in the periphery is laminated and joined before lamination, the processing (cutting) is performed as described above. Deformation and distortion of the metal plate 2 accompanying this are a problem. However, the vacuum forming mold has a characteristic that a load applied to the mold is relatively small and a vacuum suction channel needs to be formed, so that the metal plates are joined locally. For this reason, even if the metal plate 2 is deformed or distorted due to the processing prior to lamination, it can be dealt with with minimal repair.

  The material of the mold 40 can be reduced by laminating and bonding not only the vicinity of the cavity 3 but also the processed metal plates in the periphery. Furthermore, the weight can be reduced, the amount of processing of the cavity surface 3 is small, and the mold 40 can be manufactured at a low cost in a short time.

  As shown in FIG. 9, in the case of laminating the metal plate 2 whose outer periphery is also processed, there is a case where the metal plate has a small stacking margin and may not be easily laminated. In such a case, as shown in FIG. By positioning a reference hole 50 in a part of the metal plate 2 and inserting the reference hole 50 into a reference pin or reference bar 51, positioning can be performed easily.

  FIG. 11 is a flowchart showing a procedure for manufacturing the vacuum forming mold 1 using the metal plate 2. Of course, the combinations and order from step S1 to step S5 are merely examples and may be changed.

  In step S1, the three-dimensional CAD data of the mold is input to the computer. Based on the input three-dimensional CAD data, the computer creates slice data by the calculation means (step S2). A program for creating slice data is stored in the memory of the computer, and the calculation means creates slice data for each predetermined thickness of the metal plate 2 from the three-dimensional CAD data input in accordance with this program.

  The slice data includes shape data related to the cavity 3, data related to the cooling flow path 4, reference holes for positioning when the metal plates 2 are stacked, and the like. Moreover, when not using the metal plate 2 previously cut | disconnected by the predetermined dimension, the data for obtaining the metal plate 2 of a predetermined dimension are acquired. As described above, the thickness of the metal plate can be determined in consideration of the shape data regarding the cavity 3 and the like.

  In step S3, the metal plate is processed. The metal plate is processed by forming a cooling reference channel 4 and other reference holes for positioning when the metal plate 2 is laminated. When the metal plate 2 that has been cut to a predetermined size is not used, the metal plate is cut to obtain a metal plate having a predetermined size. Since the mold 1 is formed by processing and laminating metal plates, even if the cooling channel 4 has a complicated shape, it is easy to process each metal plate one by one. The mold can be manufactured in a short time. Further, the cross-sectional shape of the cooling channel 4 is basically a rectangular shape because the metal plate 2 is processed, and can have a larger heat transfer area near the cavity 3 than the circular groove. Is also one of the features.

  The processing of the metal plate in step S3 is mainly cutting of the metal plate, and laser cutting, plasma cutting, milling cutting, or the like can be used. These can be used alone or in combination. When burrs and dross occur in the cut portion, they are removed by a normal polishing method such as grinding by a grinder. In the case of using an adhesive for joining in the next step of lamination and joining, it is desirable to degrease the processed metal plate from the viewpoint of increasing the adhesive strength.

  Next, in step S4, the metal plates are laminated in a predetermined order at predetermined locations, and the metal plates are joined using a joining means such as an adhesive. Lamination can be carried out using a V block or the like as a reference plane. Alternatively, a method may be used in which a reference hole is provided in the metal plate 2 and this is inserted into the reference pin. When the adhesive 5 is used for joining the metal plates, the adhesive 5 is applied to a predetermined position of each metal plate 2 and then the next metal plate is laminated. A joined body can be formed by repeating this process sequentially. The metal plates are joined by adjacent metal plates for all the metal plates. Thereby, a metal plate is united and a joined body is formed. At this time, for joining the metal plates adjacent to each other where it is necessary to form a vacuum suction flow path, an adhesive is applied to both sides so that the air is not sucked, and an adhesive is applied locally. . Thereby, a flow path for vacuum suction can be formed.

  When the joining of all the metal plates is completed, it is possible to make the gaps between the metal plates substantially the same at each place by applying a load for a predetermined time in the stacking direction of the mold 1, and further joining between the metal plates. Power increases. In the case where diffusion bonding is performed on the metal plate 2 having the cooling flow path 4, diffusion bonding is performed only on a predetermined metal plate in advance, and this is laminated and bonded to another metal plate via an adhesive 5. May be.

  Next, in step S5, the joined body of metal plates is machined to form the cavity 3. Machining is performed based on the shape data created by the calculation means based on the three-dimensional CAD data. The apparatus used for machining is not particularly limited, and a conventionally used machining center or the like can be used. Through the above steps, a vacuum molding die can be manufactured at a low cost in a short time.

  FIG. 12 is a flowchart showing a procedure for manufacturing the vacuum forming die 40 using the metal plate 2. Of course, the combinations and order from step S11 to step S15 are only examples and may be changed.

  In step S11, the three-dimensional CAD data of the mold is input to the computer, and in step S12, slice data is created. Since step S11 and step S12 correspond to step 1 and step S2 in FIG. 11, the description of the same operation and the like is omitted.

  In step S13, the metal plate is processed. The metal plate is processed by processing a region for forming a cavity 3 including a machining allowance described later, and an outer peripheral surface of the mold. This operation is different from the content of step 3 in FIG. In addition, a reference hole for positioning when the metal plate 2 is laminated is processed as necessary. Other processing procedures for the metal plate are the same as in step S3.

  Next, in step S14, the metal plates are laminated in a predetermined place in a predetermined order, and the metal plates are joined using the joining means. Here, the case where welding is used for joining the laminated metal plates 2 will be described. When the reference hole is provided in the metal plate 2, the lamination is positioned by inserting the reference hole into the reference pin. Every time the metal plate is laminated at a predetermined position or after all the metal plates 2 are laminated, a part of the outer periphery of the metal plate 2 is locally welded. As a result, a joined body can be obtained, and a vacuum suction channel can be formed between the metal plates 2.

  Next, in step S15, the joined body of metal plates is machined to form the cavity 3. Machining is performed based on the shape data created by the calculation means based on the three-dimensional CAD data. Since the cavity is formed with the machining allowance remaining in the joined body, the amount of machining work is small, and machining can be performed in a short time. The apparatus used for machining is not particularly limited, and a conventionally used machining center or the like can be used. Through the above steps, a vacuum molding die can be manufactured at a low cost in a short time.

It is a figure which shows a part of sectional drawing of the female type | mold 1 which is a vacuum forming metal mold | die as a 1st Embodiment of this invention. It is an enlarged view which shows a part of II section of FIG. 1, and is a figure which shows the flow path for vacuum suction formed between metal plates. 3 (a), 3 (b), and 3 (c), the adhesive 5 is locally applied to the metal plate 2 for forming the vacuum suction flow path 6 of the mold 1 shown in FIG. It is a figure which shows the state applied. 4 (a) and 4 (b) show a state where the adhesive 5 is locally applied to the metal plate 2 where the vacuum suction flow path 6 of the mold 1 shown in FIG. 1 cannot be formed. FIG. It is a figure which shows the other Example of the formation method of the flow path for vacuum suction of the female type | mold 1 which is a vacuum forming metal mold | die as the 1st Embodiment of this invention. It is a figure which shows the further another Example of the formation method of the flow path for vacuum suction of the female type | mold 1 which is a vacuum forming metal mold | die as the 1st Embodiment of this invention. It is a figure which shows a part of sectional drawing of the female type | mold 20 which is a vacuum forming metal mold | die as the 2nd Embodiment of this invention. It is a figure which shows a part of sectional drawing of the female die 30 which is a vacuum forming metal mold | die as the 3rd Embodiment of this invention. It is a figure which shows a part of sectional drawing of the female type | mold 40 which is a vacuum forming metal mold | die as the 4th Embodiment of this invention. It is a figure which shows the positioning method of the lamination | stacking of the metal plate 2 when manufacturing the female die 40 of FIG. It is a flowchart which shows the procedure which manufactures the female type | mold 1 which is a vacuum forming metal mold | die as the 1st Embodiment of this invention. It is a flowchart which shows the procedure which manufactures the female die 40 which is a vacuum forming die as the 4th Embodiment of this invention.

Explanation of symbols

1, 20, 30, 40 Vacuum mold (female)
2, 31, 41, 42 Metal plate 3 Cavity 4 Cooling flow path 5 Adhesives 6, 43 Vacuum suction flow path 8 Lower surface 11 Plate body 12 Groove

Claims (8)

A vacuum forming mold for forming, joining and processing a plurality of metal plates,
A plurality of stacked metal plates forming a cavity;
A vacuum forming mold comprising: a metal plate that forms a cavity; and a vacuum suction channel that is formed by a gap between the joint surfaces of the metal plate. A vacuum forming mold for forming, joining and processing a plurality of metal plates,
A plurality of stacked metal plates forming a cavity;
A plate-like body and / or a rod-like body sandwiched between the metal plate forming the cavity and the metal plate,
A vacuum molding die comprising: a metal plate joined with the plate-like body and / or rod-like body sandwiched therebetween, and a vacuum suction channel formed between the metal plate and the metal plate. A vacuum forming mold for forming, joining and processing a plurality of metal plates,
A plurality of stacked metal plates forming a cavity;
A groove is provided in at least a part of the metal plate forming the cavity, the metal plate provided with the groove and the metal plate are joined, and a vacuum suction flow path formed on a joint surface between the metal plate and the metal plate; A vacuum forming mold characterized by including:   The vacuum forming die according to any one of claims 1 to 3, further comprising a cooling channel inside.   The vacuum forming mold according to claim 4, wherein the cooling flow path is provided along the cavity. Creating slice data from 3D CAD data;
Processing a plurality of metal plates into a predetermined shape based on the three-dimensional CAD data;
Laminating the processed metal plate at a predetermined position, joining the metal plate using a joining means, and forming a joined body;
Processing the joined body to form a cavity;
The at least part of the joining of the metal plates performed using the joining means is a local joining, leaving a gap serving as a vacuum suction channel between the metal plates. Production method. A manufacturing method of a vacuum molding die provided with a cooling channel inside,
Creating slice data from 3D CAD data;
Processing a plurality of metal plates into a predetermined shape based on the three-dimensional CAD data;
Laminating the processed metal plate at a predetermined position, and joining the metal plate using a joining means to form a joined body;
Processing the joined body to form a cavity, and
Of the joining of the metal plates performed using the joining means, the part forming the cooling channel is joined to the entire circumference of the cooling channel, and at least a part of the other part is locally joined. A method for manufacturing a vacuum forming mold, characterized in that a gap is formed between the metal plates to form a vacuum suction flow path.   The method for manufacturing a vacuum forming mold according to claim 6 or 7, wherein the joining means is an adhesive.

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