JP2010012698A - Extrusion mold - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an extrusion mold which can carry out stable production by suppressing the occurrence of damage in a molding when the molding having a hollow hole is molded by extruding a molding material. <P>SOLUTION: The extrusion mold A has a support part 1 in which a circulation hole 3 which partitions the passage of the molding material back and forth and penetrates the passage back and forth and a plurality of projections 2 projecting from the support part 1 forward. A ventilation hole 17 penetrating back and forth is formed in the projection 2. A ventilation route 21 through which an air current supplied from the outside circulates and which communicates with the ventilation hole 17 of the projection 2 is formed in the support part 1. The support part 1 and the projection 2 are connected to each other by uneven engagement between a connection hole 18 formed on the front side of the support part 1 and a connection part 16 formed at the rear end of the projection 2. An outside taper in which an outer diameter becoming smaller toward the rear end side is formed on the peripheral surface of the connection part 16, and an inside taper corresponding to the outside taper is formed on the inner surface of the connection hole 18. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an extrusion mold for forming a molded body having a hollow hole by extruding a molding material such as a cement-based molding material.

  A molded body B (see FIG. 20) having a plurality of hollow holes 23 formed by extruding a molding material such as a cement-based molding material is used as an outer wall of a building.

  As an extrusion mold A for producing such a molded body B, the present applicant has proposed the one shown in FIG. The extrusion mold A is composed of a main body mold 81 having a flow path 83 through which a molding material flows and a core mold 82 disposed in the flow path 83 in the main body mold 81. The core mold 82 includes a support body 84 and a plurality of protrusions 2 ′ protruding from the support body 84 in the flow direction of the molding material. The protrusions 2 ′ are aligned in parallel along the flow path 83. And the rows of the protrusions 2 'are provided in a staggered manner in a row in a direction orthogonal to the arrangement direction. The support 84 is branched by the branching portion 86 that branches the flow direction of the molding material flowing through the flow path 83 in the stacking direction between the rows of the protruding portions 2 ′ adjacent in the stacking direction. Further, a branch path 87 is provided that branches the flow direction of the molding material between the adjacent protrusions 2 ′ in each row. In such an extrusion mold A, when forming the molded body B having the hollow hole 23, it can be molded without applying excessive pressure, and the molding material is sufficiently filled between the hollow holes 23 and obtained. Stable production can be performed by preventing the occurrence of a decrease in the strength of the molded product B.

  When the molded body material is extruded using such an extrusion mold, the molded body B having the hollow holes 23 is continuously formed, and the air flows into the hollow holes 23 of the obtained molded body B. Thus, the internal pressure of the hollow hole 23 is equivalent to the outside of the molded body B.

  However, when a part of the hollow hole 23 is buried due to some trouble in the extrusion molding process of the molding material, air is not supplied into the hollow hole 23 formed thereafter, and the pressure inside the hollow hole 23 is not supplied. May become very low. In such a case, the formed molded body B is in a state where breakage is likely to occur due to a pressure difference between the inside and the outside of the hollow hole 23, and the hollow hole 23 is sequentially crushed during the forming, and the hollow hole 23 is not formed. The molded body B may be damaged when a load is applied when the molded body B is cut.

  Therefore, the applicant of the present invention has provided the ventilation hole 17 penetrating in the flow direction of the molding material in the projection 2 ′ for forming the hollow hole 23, and the support portion 1 ′ supporting the projection 2 ′ (the above conventional one). It is proposed that an air flow supplied from the outside flows in the support body 84 in the technology) and that an air passage 21 ′ communicating with the air hole of the protrusion 2 ′ is provided (Japanese Patent Application No. 2007-255396). . In this case, when the molding material is extruded to obtain the molded body B, the internal pressure of the hollow hole 23 is prevented from being reduced by flowing the air flow into the hollow hole 23 through the vent path 21 ′ and the vent hole 17. It is possible to suppress the breakage of the molded body B due to the internal pressure becoming smaller than the external pressure.

  When such a protrusion 2 ′ is provided on the support 1 ′, as shown in FIG. 22, a male screw groove is formed in the connection portion 16 ′ at the rear end of the protrusion 2 ′, and the support 1 ′ It is conceivable to provide a connection hole 18 ′ having a female spiral groove and to join them by screwing them together.

However, in this case, if a male screw groove is provided at the rear end of the projection 2 ′ having the vent hole 17, the thickness between the outer surface of the projection 2 ′ and the inner surface of the vent hole 17 is reduced at the spiral valley portion. Therefore, in order to ensure sufficient strength, the ratio of the inner diameter dimension of the vent hole 17 to the outer diameter dimension of the protrusion 2 ′ must be reduced, and the smooth flow of the airflow in the vent hole 17 can be ensured. There is a risk of disappearing. In this case, the internal pressure of the hollow hole 23 cannot be sufficiently increased, and a difference is generated between the external pressure of the molded body B and the internal pressure of the hollow hole 23, and damage to the molded body B is sufficiently suppressed. There is a risk that it will not be possible.
JP 2007-296747 A

  The present invention has been made in view of the above points. In forming a molded body having a hollow hole by extruding a molding material such as a cement-based molding material, a part of the hollow hole is formed in the extrusion process. Extrusion that can suppress the decrease in the internal pressure of the hollow hole and suppress the occurrence of breakage in the molded body and perform stable production even when a situation such as being buried due to some trouble occurs. An object is to provide a mold.

  The extrusion mold A according to the present invention is used to form a molded body B having a plurality of hollow holes 23 by extruding a molding material. This extrusion mold A includes a support portion 1 that divides a flow path of a molding material in the front-rear direction and is formed with a flow hole 3 penetrating in the front-rear direction. Moreover, the some protrusion 2 which protrudes toward the front from this support part 1 is comprised. The projection 2 is provided with a vent hole 17 penetrating in the front-rear direction, and an air flow path 20, 21 communicating with the vent hole 17 of the projection 2 while an air flow supplied from the outside flows through the support portion 1. , 26 are provided. The support part 1 and the protrusion 2 are connected by an uneven fitting between a connection hole 18 provided on the front side of the support part 1 and a connection part 16 provided at the rear end of the protrusion 2. The outer peripheral surface of the connecting portion 16 is formed with an outer taper whose outer diameter becomes smaller toward the rear end side, and the inner surface of the connection hole 18 is formed with an inner taper that matches the outer taper.

  In addition, let the forward direction of the extrusion direction of the molding material by the extrusion mold A be the front, and let the reverse direction be the back.

  According to the present invention, when the molding material is extruded to obtain the molding B, the molding material has the hollow hole 23 by passing through the flow hole 3 of the support portion 1 and the projection 2. B can be molded. By reducing the internal pressure of the hollow hole 23 by flowing the air flow into the hollow hole 23 through the ventilation paths 20 and 21 and the ventilation hole 17 at the time of molding. Further, the connection between the protrusion 2 and the support portion 1 is due to the concave and convex fitting between the connection portion 16 formed with the outer taper and the connection hole 18 formed with the inner taper. Connected firmly. Furthermore, it is no longer necessary to form a male screw groove in the connection portion 16 of the protrusion 2, and the thickness between the inner surface of the vent hole 17 and the outer surface of the connection portion 16 is not reduced by the spiral valley. The ratio of the inner diameter dimension of the vent hole 17 to the outer diameter dimension of the portion 2 can be increased, and the smooth flow of the air flow in the vent hole 17 is ensured, and the reduction of the internal pressure of the hollow hole 23 is further reliably suppressed. be able to.

  In the present invention, the taper angle of the outer taper of the connecting portion 16 is preferably in the range of 1.0 ° to 5.0 °. In this case, the concave / convex fitting between the connecting portion 16 and the connecting hole 18 becomes very strong.

  According to the present invention, a molded body having a hollow hole by allowing a molding material to flow through the flow hole of the support portion during extrusion molding and flowing an air flow into the hollow hole through the vent passage of the support portion and the vent hole of the protrusion. When molding the inner diameter of the vent hole, it is possible to ensure that the airflow can flow smoothly, preventing the internal pressure of the hollow hole from being reduced, and reducing the pressure outside the molded body and the internal pressure of the hollow hole. It is possible to suppress the occurrence of the difference between the two and the molded body to sufficiently prevent the breakage.

  A first embodiment will be described with reference to FIGS. As shown in FIGS. 1, 5, 6, 9, and 10, the illustrated extrusion mold A includes a base portion 8, a base portion 9, a support portion 1, and a protrusion 2 (hollow pin).

  Hereinafter, the configuration of the extrusion mold A will be described with the forward direction of the extrusion direction of the molding material by the extrusion mold A being the front and the reverse direction being the rear.

  The base portion 8 is formed in a cylindrical shape with both front and rear surfaces opened, and the molded body B after extrusion molding is pushed out from the opening on the front end side. Moreover, the collar part 10 is extended toward the outer periphery direction from the outer periphery of the edge part of the rear-end side of the nozzle | cap | die part 8. As shown in FIG. The hollow portion 11 inside the base portion 8 constitutes a flow path for the molding material, and the molding material flows in the hollow portion 11. In the illustrated example, in order to mold the plate-shaped molded body B, the cross-sectional shape of the hollow portion 11 is formed in a rectangular cross section in which a pair of opposing sides is longer than the other pair of opposing sides. .

  The base portion 9 is formed of a plate-like body having one surface disposed on the front side and the other surface on the rear side. The base portion 9 is provided with a hollow portion 12 penetrating in the front-rear direction at a position matching the hollow portion 11 of the base portion 8. The hollow portion 12 also constitutes a flow path for the molding material, and the molding material flows in the hollow portion 12 toward the front of the base portion 9.

  The support part 1 is provided so as to be interposed between the flange part 10 and the base part 9 of the base part 8, and is constituted by a hollow part 11 of the base part 8 and a hollow part 12 of the base part 9. It is provided so as to partition the flow path of the molding material back and forth. The support portion 1 is formed of a plate-like body, and the front surface thereof overlaps with the back surface of the collar portion 10 and the back surface overlaps with the front surface of the base portion 9. A plurality of protrusions 2 are provided on the front surface of the support part 1 along the flow direction of the molding material. This protrusion 2 is accommodated in the hollow part 11 of the base part 8 so as to protrude forward from the support part 1. The support portion 1 is provided with a plurality of flow holes 3 penetrating the support portion 1 in the front-rear direction. The flow holes 3 are formed between the hollow portion 12 of the base portion 9 and the hollow portion 11 of the base portion 8. The molding material is distributed.

  In addition, a plurality of communication holes 13 are formed at positions corresponding to each other in the flange portion 10, the support portion 1, and the base portion 9 of the base portion 8, and the communication holes 13 are connected to the base portion 8, In order to attach the support part 1 and the base part 9 to the extrusion molding machine as a reference for alignment when the extrusion mold A is configured, or to insert an appropriate fixing tool such as a bolt into the communication hole 13. Or can be used.

  The structure of the support part 1 and the protrusion 2 in this embodiment is demonstrated in detail.

  A plurality of protrusions 2 are provided in parallel and parallel, and the front end surfaces of the plurality of protrusions 2 are all flush with each other. The protrusion 2 shown in the figure has a cylindrical shape, but the protrusion 2 is formed in another appropriate shape such as a hexagonal column depending on the shape of the hollow hole 23 formed in the molded body B. The plurality of protrusions 2 are provided so as to be spaced apart from each other and arranged in a planar hexagonal lattice shape. That is, as shown in FIG. 7 and the like, the interval between the adjacent protrusions 2 is formed to be constant, and the six protrusions 2 surround the one protrusion 2 in a regular hexagonal shape and the center. The distance between the protrusions 2 and the surrounding protrusions 2 and the distance between the surrounding protrusions 2 are all made equal. In FIG. 7, some of the protrusions 2 are indicated by broken lines.

  As shown in FIG. 2, each protrusion 2 is composed of a main portion 25, a large diameter portion 15, a large diameter portion 14, and a connection portion 16. The main portion 25 is formed in a cylindrical shape having a uniform outer diameter. The large diameter portion 14 is formed at the front end portion of the protrusion 2 and is formed in a columnar shape having an outer diameter larger than that of the main portion 25. The enlarged diameter portion 15 is interposed between the main portion 25 and the large diameter portion 14 and is formed so that the outer diameter gradually increases toward the large diameter portion 14.

  The connecting portion 16 is formed at the rear end portion of the protrusion 2 so as to be connected to the main portion 25, and an outer taper is formed on the outer peripheral surface of the connecting portion 16 so that the outer diameter becomes smaller toward the rear end side. For this reason, the diameter of the front end portion of the connecting portion 16 is the same as that of the main portion 25, and the diameter of the rear end portion is smaller than that of the main portion 25. The taper angle of the outer taper of the connecting portion 16 is preferably in the range of 1.0 ° to 5.0 °.

  As shown in FIGS. 1, 2, 7, 9 and the like, the protrusion 2 is provided with a vent hole 17 penetrating through the inside thereof.

  An interval between adjacent protrusions 2 (an interval between large-diameter portions 14) is appropriately set. If this interval is reduced, the interval between the hollow holes 23 formed in the molded body B is reduced, which contributes to weight reduction. However, it is preferable to leave an interval that can give sufficient strength to the molded body B. For example, when a cement-based molding material is used as the molding material, the interval is preferably 1.5 mm or more. Moreover, it is preferable that the internal diameter of the vent hole 17 is 1 mm or more.

  On the other hand, the support part 1 is formed of a plate-like body whose one side is disposed forward and the other side is disposed rearward. The support 1 is configured by overlapping a plate-shaped front body 1a (see FIGS. 3 and 4) disposed on the front side and a plate-shaped rear body 1b disposed on the rear side.

  In the front body 1a, a plurality of connection holes 18 penetrating in the front-rear direction are provided at positions corresponding to the protruding positions of the protrusions 2. In other words, the openings of the plurality of connection holes 18 are arranged inside a rectangular region that is arranged in a planar hexagonal lattice pattern on both surfaces of the front body 1 a and matches the arrangement of the protrusions 2.

  An inner taper that matches the outer taper of the connection portion 16 of the protrusion 2 is formed on the inner surface of the connection hole 18, and the protrusion is formed by fitting the connection portion 16 of the protrusion 2 into the connection hole 18. The part 2 protrudes from the support part 1 (see FIG. 1 and the like). The rear end of the connection hole 18 communicates with a hollow connection space 19 that opens on the back surface of the support portion 1.

  In this way, the connection between the protrusion 2 and the support portion 1 is achieved by the concave-convex fitting between the connection portion 16 formed with the outer taper and the connection hole 18 formed with the inner taper. The protrusion 2 is firmly connected to the support 1 without forming a spiral groove in the hole 18. In particular, when the taper angle of the outer taper of the connecting portion 16 is in the range of 1.0 ° to 5.0 ° as described above, the concave-convex fitting becomes very strong. For this reason, when forming the vent hole 17 in the protrusion 2, it is not necessary to consider the strength reduction due to the spiral valley of the male screw groove formed in the connection portion 16, and the inner diameter of the vent hole 17 with respect to the outer diameter of the protrusion 2 is eliminated. The ratio of dimensions can be increased. That is, for example, when the outer diameter of the main portion 25 of the protrusion 2 is 3.5 mm, the inner diameter of the vent hole 17 can be formed up to 2 mm.

  Further, when the outer taper is formed in the connection portion 16 and the inner taper is formed in the connection hole 18 in this way, it is not necessary to form a spiral groove when the protrusion 2 and the support portion 1 are formed. Breakage such as bending or bending is suppressed when the support portion 1 is manufactured, and thus the protrusion 2 and the support portion 1 can be easily manufactured. Further, since the processing is easy, the processing accuracy is increased. Further, when attaching or detaching the support portion 1 and the protrusion 2, the support portion 1 or the protrusion 2 can be easily attached or detached by slightly twisting or lightly tapping the support portion 1 or the protrusion 2.

  In addition, the support portion 1 is provided with a main air passage 20 and a branch air passage 21 as the air passages 20 and 21 that serve as air flow paths.

  The main air passage 20 opens on the back surface outside the rectangular region (the region where the projecting portion 2 projects) where the opening of the connection hole 18 is provided on the back surface of the front body 1a. It is recessed in the shape of a groove. The main air passage 20 is provided along the long side outside the two long sides facing each other in the rectangular region.

  A plurality of branch air passages 21 are provided in parallel in parallel between the two main air passages 20 so as to communicate with each main air passage 20 at both ends and open to the back surface. The branch air passage 21 is formed inside a rectangular region where the opening of the connection hole 18 is provided, and each branch air passage 21 sequentially connects the connection spaces 19 of the plurality of connection holes 18 in the region. It is provided to cross. As a result, the connection spaces 19 of all the connection holes 18 communicate with any one of the branch ventilation paths 21.

  Openings on the back side of the main air passage 20, the branch air passage 21, and the connection space 19 are closed by the rear body 1b. Therefore, the main air passage 20, the branch air passage 21, and the connection space 19 are supported by the support portion 1. Provided inside. In this way, the support portion 1 is formed by the front body 1a and the rear body 1b, and the main ventilation path 20, the branch ventilation path 21 and the connection space 19 are formed in a space sandwiched between the front body 1a and the rear body 1b. By forming, the main ventilation path 20, the branch ventilation path 21, and the connection space 19 which have a complicated form in the inside of the support part 1 can be formed easily. Here, in the illustrated embodiment, the front body 1a is recessed to form the main ventilation path 20, the branch ventilation path 21, and the connection space 19 at the back, and the main ventilation path 20, the branch ventilation path. 21 and the opening of the connection space 19 are closed by the rear body 1b. However, the present invention is not limited to such a configuration. For example, at least any of the main ventilation path 20, the branch ventilation path 21, and the connection space 19 is provided in the rear body 1b. Alternatively, the front body 1a may be closed.

  The main ventilation path 20 may be formed outside the area where the opening of the connection hole 18 (connection space 19) is provided (the area where the protrusion 2 is projected). The position where 21 is formed may be a position that crosses all the connection spaces 19 inside the region, but the main air passage 20 is arranged outside the outer edges on both sides along the longitudinal direction of the region as described above. If a plurality of branch air passages 21 are formed in parallel with each other along the short direction of the region so as to connect the main air passage 20, the plurality of branch air passages 21 are formed in parallel with each other. The path length of the ventilation path 21 can be formed as short as possible.

  In addition, an air supply path 22 that communicates with the main ventilation path 20 and that opens at the outer peripheral surface of the front body 1a and communicates with the outside of the support section 1 is provided inside the front body 1a. Two air supply passages 22 are provided for each main air passage 20, and a total of four air supply passages 22 are provided.

  The plurality of flow holes 3 provided in the support portion 1 have rear ends that open at the back surface of the support portion 1 and communicate with the hollow portion 12 of the base portion 9, and front ends that open at the front surface of the support portion 1. The base portion 8 communicates with the hollow portion 11 so as to penetrate the support portion 1 in the flow direction of the molding material.

  The plurality of flow holes 3 are provided at positions that surround the plurality of protrusions 2 protruding from the support portion 1, and are provided so as to uniformly surround the protrusion 2. That is, the plurality of flow holes 3 provided around each protrusion 2 are formed such that the intervals between the protrusions 2 and the flow holes 3 are all equal and the intervals between the flow holes 3 are all equal. Is done. In the illustrated example, each flow hole 3 is formed at a central position surrounded by three protrusions 2, and each protrusion 2 is a center surrounded by six flow holes 3 arranged in a regular hexagon. It is formed in a position, and thereby, the distance between each protrusion 2 and each surrounding circulation hole 3 is constant, and the distance between each surrounding circulation hole 3 is constant. .

  Each of the plurality of flow holes 3 is provided with an outflow side taper portion 4 whose inner diameter increases toward the front on the inner peripheral surface on the front end side. The outflow side taper portion 4 is provided on the front body 1 a of the support portion 1. In addition, an inflow side taper portion 5 whose inner diameter increases toward the rear is provided on the inner peripheral surface on the rear end side of each flow hole 3. The inflow side taper portion 5 is provided on the rear body 1 b of the support portion 1.

  At this time, the outflow side taper portions 4 of the adjacent circulation holes 3 are formed adjacent to each other on the front surface of the support portion 1 and are surrounded by a plurality (six in the drawing) of the outflow side taper portions 4. A flat region 24 in which the connection hole 18 is formed is secured at the position (see FIG. 7).

  As shown in FIGS. 6, 8, 10, etc., the back surface of the support portion 1 is formed so that the inflow side taper portions 5 of the adjacent flow holes 3 are adjacent to each other. A ridge portion 6 is formed at the boundary between the portions 4. Since both sides of the ridge portion 6 are formed with the outflow side taper portion 4, each ridge portion 6 is inclined downward toward the front side. The ridge portion 6 is formed in a straight line when viewed from the rear, and the ridge line of the ridge portion 6 is formed so as to be recessed forward. At this time, the flow hole 3 is formed at a position surrounded by a plurality of (three in the drawing) ridges 6. Moreover, the top part 7 which protrudes toward back is formed in the position (position which agree | coincides with the formation position of the connection hole 18) where the edge parts of several (six in the illustration) ridge parts 6 cross | intersect. In the example shown in the drawing, a flat area having a small area is formed at the tip of the top portion 7. More preferably, the tip of the top portion 7 is formed in a pointed shape.

  In addition, in FIG. 3, illustration of the inflow side taper part 5, the ridge part 6, and the top part 7 in the rear part 1b is abbreviate | omitted.

  Next, the shaping | molding of the molded object B using the extrusion mold A formed in this way is demonstrated.

  The above-described extrusion mold A is attached to an appropriate extrusion molding apparatus, an extrusion pressure is applied to the molding material, and the molding material is supplied from the base portion 9 side to the molding material flow passage in the extrusion molding die A. The molded product B is molded by being extruded from the front opening.

  Although it will not restrict | limit especially if it is a material used for extrusion molding as a molding material, Especially a cement-type molding material can be used. As the cement-based molding material, one having an appropriate composition can be used, for example, it is prepared by blending aggregate, fiber, colorant and the like with cement as necessary, and kneading with water. As the cement, any material such as ordinary Portland cement, slag cement, alumina cement, or early-strength cement can be used. In addition, as the aggregate, silica, silica powder, silica sand, fly ash, slag, crushed stone, and the like can be used. As the fiber, polypropylene fiber, vinylon fiber, acrylic fiber, pulp, carbon fiber, cotton, hemp, metal fiber and the like can be used. Further, iron black, carbon black, chromium oxide, or the like can be used as a colorant.

  In particular, as a cement-based molding material, it contains an oily substance and further contains an emulsifier (inverse emulsifier) such as a nonionic surfactant, various anionic surfactants, and a cationic surfactant as necessary. It is also preferable to use what forms an inverse emulsion (W / O emulsion). Since such an inverse emulsion type cement-based molding material has a certain shape-retaining property, the shape can be maintained when the molded body B having the hollow holes 23 is molded. As will be described later, extrusion can be performed without applying excessive pressing force, and the destruction of the inverse emulsion structure at the time of molding can be suppressed, thereby preventing the subsequent curing and curing from being hindered. it can.

  The oily substance is not particularly limited as long as it can form an inverse emulsion with water, and usually a hydrophobic liquid substance is used. For example, toluene, xylene, kerosene, styrene, divinylbenzene, methyl methacrylate, Examples include trimethylolpropane trimethacrylate and unsaturated polyester resins. Among these, when using those having a polymerizable double bond (vinyl monomer) such as styrene, divinylbenzene, methyl methacrylate, trimethylolpropane trimethacrylate, unsaturated polyester resin, etc. In order to accelerate the polymerization of the oily substance, a polymerization initiator such as an organic peroxide or a persulfate, or a crosslinking agent such as trimethylolpropane trimethacrylate can be used in combination.

  In this extrusion molding, when the molding material passes through the support portion 1 and the protrusion 2, the molding material first flows into each flow hole 3 of the support portion 1 and branches, and after passing through this flow hole 3, The molding material passes between the plurality of protrusions 2 and flows in parallel along the protruding direction of the protrusions 2 around the protrusions 2 between the adjacent protrusions 2. At this time, the molding material flows out from the flow holes 3 formed so as to be evenly arranged at positions surrounding the periphery of the protrusion 2, thereby causing an even flow of the molding material around the protrusion 2. For this reason, the molding material can be sufficiently filled around the protrusion 2 without applying a high extrusion pressure. In addition, while the molding material flows between the protrusions 2 in this way, the molding material flowing around the protrusions 2 becomes familiar and integrated.

  In such a flow of the molding material, when the molding material flows into the flow hole 3 from the hollow portion 12 of the base portion 9, the ridge portion 6 and the top portion 7 formed on the back surface of the support portion 1 are used. The molding material is easily branched and guided to the flow hole 3. In particular, when the tip of the top portion 7 is formed in a pointed shape, deposition of the molding material on the top portion 7 is suppressed, and the inflow of the molding material into the flow hole 3 is further promoted. Furthermore, the inflow side taper part 5 is provided in the rear-end part of the circulation hole 3, and the inflow to the circulation hole 3 of a molding material is accelerated | stimulated.

  For this reason, the extrusion pressure required for the molding material to pass through the flow holes 3 can be reduced, and the pressure applied to the molding material can be suppressed.

  Further, when the molding material flows out from each flow hole 3 to the hollow portion 11 side of the base portion 8, the flow-out hole 3 is provided with the outflow side taper portion 4, so that the molding material spreads in the lateral direction. It will be leaked. For this reason, the fluidity | liquidity at the time of a molding material flowing out from the flow hole 3 improves, and deposition of a molding material can be suppressed. Further, the filling property around the protrusions 2 when the molding material passes between the protrusions 2 can be further improved, and the familiarity between the molding materials around the protrusions 2 can be further improved. .

  Then, the molding material B having a hollow hole 23 as shown in FIG. 20 is formed by extruding the molding material from the front opening of the base portion 8. FIG. 20A shows a molded body B obtained when the cylindrical protrusion 2 is applied as in this embodiment, and has a hollow hole 23 having a circular cross section. Further, when a hexagonal columnar shape is applied as the protrusion 2, a molded body B having a hollow hole 23 having a hexagonal cross section as shown in FIG. 20B can be obtained, and other appropriate shapes can be obtained. By adopting the protrusion 2, a molded body B having a hollow hole 23 having a desired shape can be obtained.

  The obtained molded body B is cut so as to have a desired dimension as required, and is cured and cured as necessary, particularly when formed of a cement-based molding material.

  Further, in the extrusion molding process as described above, an air flow such as air is supplied from an opening outside the support portion 2 of each air supply path 22. For this reason, the supplied airflow flows into each main ventilation path 20 from each supply path 22 and further branches into each of the plurality of branch ventilation paths 21. At this time, airflow flows into the plurality of branch air passages 21 from the end portions on both sides thereof. Then, the airflow flows from the branch ventilation paths 21 into the vent holes 17 in the projections 2 through the connection spaces 19 and flows out from the front openings of the projections 2. For this reason, airflow such as air is supplied to the hollow holes 23 formed in the molded body B.

  When airflow is supplied to the hollow hole 23 of the molded body B in this way, it is possible to prevent the pressure in the hollow hole 23 from being lowered and to prevent the hollow hole 23 from being buried.

  In addition, when a part of the hollow hole 23 is buried due to some trouble during the extrusion molding process of the molding material, air is not supplied into the hollow hole 23 formed thereafter, and the pressure inside the hollow hole 23 is reduced. It can be very low. In such a case, the formed molded body B is likely to be damaged due to a pressure difference between the inside of the hollow portion and the outside. For this reason, there is a possibility that the hollow holes 23 are sequentially crushed during molding, and the hollow holes 23 may not be formed. Further, even when the hollow holes 23 are formed, a load is applied to cut the molded body B. The molded body B may be damaged. However, when the airflow is supplied to the hollow hole 23 of the molded body B as described above, it is possible to prevent the pressure inside the hollow hole 23 from being lowered even if a part of the hollow hole 23 is buried. , Damage to the molded body B as described above can be prevented. In particular, in this embodiment, since the ratio of the inner diameter dimension of the vent hole 17 to the outer diameter dimension of the protrusion 2 can be increased, a smooth flow of the airflow in the vent hole 17 is ensured, and the hollow hole 23 Reduction of the internal pressure is further reliably suppressed.

  Here, if the pressure of the air flow supplied into the hollow hole 23 is too high, the molded body B may be damaged due to the difference between the pressure inside the hollow hole 23 and the pressure outside the molded body B. The pressure of the airflow is preferably a pressure near atmospheric pressure. At this time, when the flow resistance of the airflow flowing out from the air supply passage 22 through the main air passage 20, the branch air passage 21, the connection space 19, and the air vent 17 is large, the air flow is reduced at a low pressure close to the atmospheric pressure. It becomes difficult to supply.

  However, in this embodiment, the path length of the branch air passage 21 is formed as short as possible as described above, and the air flow is supplied from both ends of the branch air passage 21, so the air flow in the branch air passage 21 is as follows. The maximum path length is ½ of the length of the branch ventilation path 21 at the maximum. For this reason, the whole path | route length of airflow becomes short, and flow-path resistance is reduced. Moreover, since the number of the vent holes 17 of the protrusion 2 connected to each branch vent path 21 can be reduced, the flow path resistance is further reduced. In addition, since airflow is supplied from both sides of the branch ventilation path 21 in this way, even if clogging occurs in the middle of the branch ventilation path 21, the airflow can be stably supplied to each ventilation hole 17.

  In addition, when the difference in flow resistance between the airflows flowing out from the hollow holes 23 of the protrusions 2 until the airflow flows out from the hollow holes 23 increases, the difference in pressure between the airflows increases, and the compact B There is a possibility that the pressure difference in each hollow hole 23 formed in the above becomes large, causing the molded body B to be damaged.

  However, the difference in the channel resistance is mainly caused by the difference in the path length from the time when the airflow flows into the branch ventilation path 21 to the time when the airflow flows into the vent hole 17 of each projection 2. By making the path length of the airflow in the branch air passage 21 shorter, the difference in the path length of the airflow can be made smaller, so that the airflow flowing out from the hollow hole 23 of each protrusion 2 can be reduced. The pressure difference can be reduced.

  Further, if the flow resistance in the branch air passage 21 is reduced by increasing the cross-sectional area of the surface perpendicular to the longitudinal direction of the branch air passage 21 (surface orthogonal to the air flow direction) as much as possible, This can contribute to a reduction in road resistance, and the airflow can be supplied at a lower pressure. Moreover, since the difference in flow path resistance due to the difference in path length in the branch air passage 21 can be reduced, the difference in flow path resistance between the airflows flowing out from the hollow holes 23 of the respective protrusions 2 is also reduced. The pressure difference between the airflows can be further reduced. In this case, the cross-sectional area of the branch air passage 21 is, for each branch air passage 21, the cross-sectional area of the branch air passage 21 is S, the number of airflow inflow positions in the branch air passage 21 is n, Assuming that s is the sum of the cross-sectional areas of the planes perpendicular to the longitudinal direction of the vent holes 17 of all the projections 2 connected to the branch vent path 21 (planes perpendicular to the air flow direction), S ≧ s / It is necessary to have a relationship of n, and in the present embodiment, since air flows respectively from both ends of the branch ventilation path 21, n = 2 and S ≧ s / 2 needs to be satisfied. Here, the cross-sectional area of the vent hole 17 depends on the cross-sectional area of the protrusion 2, that is, the diameter of the hollow hole 23 formed in the molded body B. If the diameter of the hollow hole 23 of the molded body B is small, the vent hole 17 Since it is necessary to reduce the cross-sectional area, it is necessary to design the cross-sectional area of the molecular air passage 21 according to the diameter of the hollow hole 23 formed in the molded body B.

  In forming the branched vent passage 21 as described above, when the protrusions 2 are formed densely in order to form the hollow portions 23 densely in the molded body B, the vent holes 17 are also formed densely. Thus, since the branch air passage 21 needs to be formed by sewing between the air holes 17, it is difficult to form the branch air passage 21 with a sufficiently large width. For this reason, in order to form the branch air passage 21 so as to have a sufficiently large cross-sectional area, it is necessary to secure a sufficient depth of the branch air passage 21. For this purpose, it is preferable to form the front body 1a so as to be sufficiently thick.

  Further, if the flow passage resistance in the main air passage 21 is reduced by increasing the cross-sectional area of the surface perpendicular to the longitudinal direction of the main air passage 20 (the surface orthogonal to the air flow direction) as much as possible, the entire flow passage Resistance can be further reduced. In particular, for each main air passage 20, if the cross-sectional area of the main air passage 20 is S 'and the sum of the cross-sectional areas of all the branch air passages 21 communicating with the main air passage 20 is s', S It is preferable to have a relationship of '≧ s'.

  FIG. 11 shows a second embodiment. This embodiment is a modification of the first embodiment. The base portion 9 in the present embodiment is formed of a cylindrical body in the front-rear direction, and a hollow portion 12 penetrating in the front-rear direction is formed inside the base portion 9 at a position that matches the hollow portion 11 of the base portion 8. Is provided. At the front end portion of the base portion 9, a front collar portion 27 protruding in the outer circumferential direction is provided over the entire circumference, and the front collar portion 27 is superimposed on the support portion 1. The communication hole 13 is formed in the front collar portion 27. Further, a rear collar portion 28 protruding in the outer circumferential direction is provided at the rear end portion of the base portion 9 over the entire circumference, and a plurality of communication holes 42 are formed in the rear collar portion 28. The communication hole 13 and the communication hole 42 are used as a reference for alignment when the die part 8, the support part 1, and the base part 9 are overlapped to form the extrusion mold A, and bolts or the like are provided in the communication holes 13 and 42. Or an appropriate fixing tool can be inserted and used to attach to an extruder. Further, the flange 10 of the base 8, the support 1, and the front flange 27 of the base 9 are connected to the side pieces 43 arranged along the both side surfaces thereof and the side pieces 43, respectively. A holding tool 45 composed of the flange portion 10 of the portion 8, the support portion 1, and the lower surface piece 44 disposed along the lower end surface of the front flange portion 27 of the base portion 9 is attached.

  Also in this embodiment, as in the case of the first embodiment, the connection portion 16 having an outer taper formed at the rear end of the protrusion 2 and the connection hole 18 having an inner taper provided in the support portion 1. , And the protrusion 2 is supported by the support portion 1.

  A third embodiment will be described. An extrusion mold A shown in FIGS. 13A and 13B and FIG. 19 includes a mold body 52 formed with an internal space as a flow path 51, and a middle mold 70 accommodated in the flow path 51 of the mold body 52. And is formed. The mold body 52 and the middle mold 70 can be formed using a metal material such as stainless steel.

  The mold body 52 is formed in a horizontally long box shape by combining a plurality of plates, and a horizontally long inlet 53 is formed on the front surface and a horizontally long outlet 57 is formed on the back surface. Is formed. The inlet 53 communicates with the material entry side of the flow path 51, and the outlet 57 communicates with the material exit side of the flow path 51.

  As shown in FIGS. 14 (a) and 14 (b), the middle mold 70 includes a plurality of hollow protrusions 2 and a support part 1 that supports the protrusions 2, and is similar to the mold body 52. It is formed horizontally. The middle mold 70 can be formed by combining and integrating a plurality of pin blocks 71, 71. As shown in FIGS. 15A to 15C, the pin block 71 is formed by providing a plurality of protrusions 2, 2... On the support bar 54, and the support portion 1 is configured by the plurality of support bars 54. .

  This protrusion 2 has the same configuration as in the first embodiment. That is, as shown in FIG. 2, each protrusion 2 is composed of a main portion 25, an enlarged diameter portion 15, a large diameter portion 14, and a connection portion 16. The main portion 25 is formed in a cylindrical shape having a uniform outer diameter. The large diameter portion 14 is formed in a cylindrical shape having an outer diameter larger than that of the main portion 25. The enlarged diameter portion 15 is interposed between the main portion 25 and the large diameter portion 14 and is formed so that the outer diameter gradually increases toward the large diameter portion 14. The size of each part of the protrusion 2 is not particularly limited. For example, the outer diameter of the main part 25 is 4 mm, the outer diameter of the large diameter part 14 is 6 mm, the overall length of the protrusion 2 is 80 mm, and the large diameter part 14 The length can be 10 mm, and the length of the enlarged diameter portion 15 can be 15 mm.

  Further, an outer taper is formed on the outer peripheral surface of the connecting portion 16 so that the outer diameter becomes smaller toward the rear end side. For this reason, the diameter of the front end portion of the connecting portion 16 is the same as that of the main portion 25, and the diameter of the rear end portion is smaller than that of the main portion 25. The taper angle of the outer taper of the connecting portion 16 is preferably in the range of 1.0 ° to 5.0 °.

  The protrusion 2 is provided with a vent hole 17 penetrating through the inside thereof along the flow direction of the molding material.

  As shown in FIGS. 16A and 16B, the support bar 54 is formed of a support member 74 and a lid member 75. The support member 74 includes a pair of upper and lower holding portions 76, 76, and attachment pieces 77 installed between the upper and lower holding portions 76, 76. A plurality of pins are provided on both side surfaces of the attachment piece 77. Bases 78, 78... Project. The pin base 78 is formed in a tubular shape that is long in the front-rear direction, and its internal space is formed as an air flow path 29. Further, the outer shape of the pin base 78 is the same as the outer shape of the main portion 25 (small-diameter portion 23) of the protrusion 2, and the inner diameter of the pin base 78 is slightly smaller than the outer diameter of the main portion 25 of the protrusion 2. Has been. Further, the plurality of pin bases 78, 78... Are formed side by side in a staggered arrangement. That is, the plurality of pin bases 78, 78... Are arranged in a zigzag manner with the mounting piece 77 interposed therebetween, and the pin base 78 provided on one side surface of the mounting piece 77 is the same as the pin base 78 provided on the other side surface. It is not at a height position but is arranged at a position slightly shifted up and down. Further, a pair of upper and lower air grooves 30, 30 are recessed on the back surface of the support member 74. The upper air groove 30 extends from a substantially central portion on the back surface of the upper holding portion 76 to a substantially central portion on the back surface of the mounting piece 77, and the lower air groove 30 is a substantially central portion on the back surface of the lower holding portion 76. To the center of the back surface of the mounting piece 77. Each air groove 30 is provided with a plurality of branch groove portions 31, and the branch groove portions 31 are formed to reach the back surface of the pin base 78. The rear end of the air flow path 29 provided in the pin base 78 opens at the bottom surface of the branch groove portion 31. Reference numeral 32 denotes a screw hole provided on the back surface of the holding portion 76. The air flow path 29 in the support portion 1 is configured by the air flow path 29, the air groove 30, and the branch groove portion 31.

  The pin base 78 of the support member 74 that constitutes the support portion 1 is provided with a connection hole 18 that opens to the front surface. An inner taper that matches the outer taper of the connection portion 16 of the protrusion 2 is formed on the inner surface of the connection hole 18. The rear end of the connection hole 18 communicates with the air flow path 29 inside the pin base 78.

  The lid member 75 has substantially the same cross-sectional shape as the support member 74, and has a pair of upper and lower holding portion lids 33, 33 and a mounting piece lid 34 that is installed between the upper and lower holding portion lids 33, 33. A plurality of pin base lids 35, 35... Project from both side surfaces of the attachment piece lid 34. In addition, an air introduction hole 59 penetrating in the front-rear direction is provided at a substantially central portion of each holding portion lid 33. Further, the corners of the attachment piece lid 34 and the pin base lid 35 of the lid member 75 are formed as a smooth tapered chamfered portion 36 by chamfering. Reference numeral 37 denotes a screw hole that penetrates the holding portion lid 33 in the front-rear direction.

  Then, the support bar 54 is formed by attaching the cover member 75 to the back surface of the support member 74 by inserting and tightening screws into the screw holes 32 and 37 with the front surface of the cover member 75 in close contact with the back surface of the support member 74. can do. By attaching the lid member 75 in this way, the air groove 30 in the holding portion 76 is closed by the holding portion lid 33, the air groove 30 in the attachment piece 77 is closed by the attachment piece lid 34, and the branch groove portion 31 in the pin base 78. Can be closed with a pin base lid 35. Further, the upper air introduction hole 59 provided in the lid member 75 is arranged at a position corresponding to the upper end portion of the upper air groove 30, and the lower air introduction hole 59 is arranged with the lower end portion of the lower air groove 30. Therefore, the air introduction hole 59 and the air groove 30 are in communication with each other.

  A pin block 71 is configured by attaching the protrusion 2 to the front side of each pin base 78 of the support portion 1. As shown in FIG. 12, the protrusion 2 is supported by the support portion 1 by fitting the connection portion 16 into the connection hole 18 that opens in the front surface of the pin base 78.

  When the protrusion 2 is attached to the pin base 78 in this way, the vent hole 17 of the protrusion 2 and the air flow path 29 of the pin base 78 are in communication with each other. Therefore, a flow path of air (airflow) reaching the air groove 30, the branch groove portion 31, the air flow path 29, and the vent hole 17 from the air introduction hole 59 of the lid member 75 can be formed. Moreover, since the pin base 78 is formed in a staggered arrangement, the protrusions 2 attached to the pin base 78 can also be arranged in a staggered arrangement.

  Then, the middle mold 70 is formed by combining and integrating the plurality of pin blocks 71, 71... When combining and integrating the plurality of pin blocks 71, 71..., First, the plurality of pin blocks 71, 71. Here, the side surfaces of the holding portions 76 and 76 of the support bars 54 and 54 of the adjacent pin blocks 71 and 71 are brought into close contact with each other. Next, long connection bases 38, 38 are arranged above and below the support bars 54, 54 ... of the plurality of pin blocks 71, 71 ... arranged in the horizontal direction, and a pair of upper and lower connection bases 38, 38 are used. A plurality of pin blocks 71, 71... Are held over the entire length in the lateral direction. Next, as shown in FIG. 17, the holding jig 39 is attached to the back surfaces of the upper and lower connection bases 38 over almost the entire length in the lateral direction. A pressing piece 40 protruding downward is projected from the upper holding jig 39, and the pressing piece 40 is in close contact with the back surface of the holding portion lid 33 on the upper side of the lid member 75 of the pin block 71. Further, a pressing piece 40 protruding upward is provided on the lower holding jig 39, and the pressing piece 40 is in close contact with the back surface of the holding portion lid 33 below the lid member 75 of the pin block 71. ing. In addition, an air supply groove 41 is formed over the entire length of each pressing piece 40, and the air supply groove 41 and the air introduction hole 59 of each pin block 71 are in communication with each other. Further, the air supply groove 41 communicates with an air inlet 50 opened on the side end surface of the connection base 38. In this way, it is possible to form the middle mold 70 in which the plurality of protrusions 2, 2... Protrude from the front end face of the connection base 38. Here, as shown in FIGS. 18 (a) and 18 (b), the flow hole 3 is formed between the support bars 54, 54 adjacent to the middle mold 70. A plurality of pin bases 78, 78... Located on both sides of the circulation hole 3 are arranged side by side in a staggered arrangement. Accordingly, the flow hole 3 is formed to meander with a substantially constant width dimension in the vertical direction.

  Moreover, the extrusion mold A of the present invention can be formed by disposing the middle mold 70 formed as described above in the flow path 51 of the mold body 52. At this time, the middle mold 70 is arranged such that the support bar 54 side is directed to the inlet 53 side of the mold body 52 and the tip of the protrusion 2 is directed to the outlet 57 side of the mold body 52 to form the flow path 51. The support bars 54, 54,... Of the middle mold 70 are positioned at a substantially central portion in the flow direction (substantially between the inlet 53 and the outlet 57). Therefore, the space at the substantially central portion of the flow path 51 is partitioned at a predetermined interval by the plurality of support bars 54, 54..., And the flow hole 3 opening toward the inlet 53 side is substantially at the central portion of the flow path 51. Will be formed. In addition, the protrusion 2 protrudes from the pin base 78 toward the outlet 57 in the flow channel 51, but is substantially straight from the pin base 78 to the tip of the protrusion 2 and parallel to the extrusion direction of the molding material. It is. In FIG. 19, the support bars 54, 54... Of the middle mold 70 are positioned substantially at the center of the flow path 51, but this is not limiting, and the inlet 53 side and the outlet 57 side from the center of the flow path 51. It may be biased to.

  The extrusion mold A of the present invention is used by being attached to an extruder. That is, by supplying the molding material from the inlet 53 of the mold body 52 to the flow path 51 by the extruder, flowing the molding material in the flow path 51 toward the outlet 57, and continuously extruding from the outlet 57, A long sheet-like molded body B made of a molding material as shown in FIG. 20 can be formed. A plurality of hollow holes 23, 13... Continuous in the longitudinal direction (extrusion direction) of the sheet can be formed in the sheet by the pin base 78 and the protrusion 2. And after cut | disconnecting the long sheet-like molded object B to desired length, it can be used as a building board etc. by carrying out curing hardening as needed. FIG. 20A shows a molded body B obtained when the cylindrical pin base 78 and the protrusion 2 are used, and has a hollow hole 23 having a circular cross section. In addition, the molded object B which has the hollow hole 23 of a desired shape can be obtained by employ | adopting the pin base 78 and the protrusion 2 of a suitable shape like FIG.20 (b).

  In the extrusion molding of the molded body B as described above, the molding material flows into the flow path 51 from the inlet 53 of the mold main body 52 and is then divided by the plurality of support bars 54, 54. 3 ... will be passed. At this time, since the edge facing the flow hole 3 of the support bar 54 such as the mounting piece 77 and the pin base 78 is formed as a chamfered portion 36 on the back surface of the middle mold 70, the flow hole 3 is formed from the inlet 53. The flowability of the molding material when passing can be improved, and the molding material can be smoothly molded without being deposited or clogged in the flow path 51. Further, since each flow hole 3 is formed to have a substantially constant width, the molding material can flow uniformly around the pin base 78 and the protrusion 2 by passing through the flow hole 3. Therefore, cutting of the molding material does not occur, and the long sheet-like molded body B having the plurality of hollow holes 23 can be stably molded.

  Further, the molding material after passing through the flow hole 3 flows toward the outlet 57 in the space around the protrusion 2 (flow path 51). At this time, the molding material separated by the support bars 54 and 54 is used. Is integrated with the interface. Moreover, since the enlarged diameter part 15 and the large diameter part 14 with a diameter larger than the main part 25 are formed in the protrusion 2 in the exit 57 side rather than the main part 25 in the protrusion 2, the periphery of the protrusion 2 is made of molding material. Is distributed gradually by the enlarged diameter portion 15, and the continuity and adhesion of the molding material can be improved. Further, the large diameter portion 14 can prevent the spring back of the molding material compressed by the enlarged diameter portion 15.

  Further, the above-described extrusion molding is performed while air (airflow) is blown out from the opening of the vent hole 17 on the front end surface of the protrusion 2. That is, an air pump or the like is connected to the air inlet 50 of the coupling base 38 of the middle mold 70 to supply air to the air supply groove 41 of the holding jig 39, and the air is supplied through the air introduction hole 59 connected to the air supply groove 41. The air passage 29, the air groove 30, and the branch groove portion 31 are supplied to the air passage 26. That is, this air is supplied to the air groove 30 of the support bar 54, and thereafter, the air supplied to the air groove 30 flows through the air flow path 29 provided in the pin base 78 through the branch groove portion 31. This air is introduced from the air flow path 29 into the vent hole 17 of the protrusion 2. Thereafter, air is blown out from the opening of the vent hole 17 on the front end surface of the protrusion 2. Then, by extruding the molding material from the outlet 57 of the flow path 51 while blowing out air (airflow) from the opening of the vent hole 17 on the front end surface of the protrusion 2 in this way, it is extruded from the outlet 57 by any chance. Even when the long sheet-like molded body B is sagging or deformed and the hollow hole 23 is partially blocked, the supply of air from the vent hole 17 prevents the inside of the hollow hole 23 from being decompressed. be able to. Therefore, the hollow hole 23 can be prevented from being continuously crushed after the portion where the hollow hole 23 is blocked.

  In the present embodiment, it is also easy to change the number of hollow holes 23 formed in the molded body B by changing the number of pin blocks 71 constituting the middle mold 70.

It is a partial sectional view showing an important section of a first embodiment of the present invention. The structure of a protrusion same as the above is shown, (a) is a side view, (b) is a sectional view. It is a disassembled perspective view which shows the structure of the support part and protrusion in 1st embodiment of this invention. FIG. 2 is a partially enlarged view of FIG. 1. 1 is a perspective view showing a first embodiment of the present invention. It is another perspective view which shows 1st embodiment of this invention. It is a front view which shows 1st embodiment of this invention. It is a partial rear view which shows 1st embodiment of this invention. It is the perspective view which fractured | ruptured partially which shows 1st embodiment of this invention. It is the other perspective view which fractured | ruptured partially which shows 1st embodiment of this invention. It is the other perspective view which fractured | ruptured partially which shows 2nd embodiment of this invention. It is a partial sectional view showing an important section of a second embodiment of the present invention. The third embodiment of the present invention is shown, (a) is a perspective view seen from the material entry side, (b) is a perspective view seen from the material exit side. The medium type | mold in 3rd embodiment of this invention is shown, (a) is the perspective view seen from the material entrance side, (b) is the perspective view seen from the material exit side. The pin block in 3rd embodiment of this invention is shown, (a) is a perspective view, (b) is a rear view, (c) is a front view. (A) is a disassembled perspective view of the pin block in 3rd embodiment of this invention, (b) is a perspective view of a supporting member. It is the perspective view which showed the intermediate mold in 3rd embodiment of this invention, and fractured | ruptured one part. The medium type | mold in 3rd embodiment of this invention is shown, (a) is a partial rear view, (b) is a partial front view. It is sectional drawing which shows 3rd embodiment of this invention. (A) And (b) is the partially broken perspective view which shows the example of a molded object. An example of a prior art is shown, (a) is sectional drawing seen from the side, (b) is CC sectional drawing of (a). It shows another example of the prior art, (a) is a cross-sectional view showing a protrusion, (b) is a side view showing the protrusion, (c) is a cross-sectional view showing a mounting state of the protrusion.

Explanation of symbols

DESCRIPTION OF SYMBOLS A Extrusion mold B Molding body 1 Support part 2 Protrusion part 3 Flowing hole 16 Connection part 17 Ventilation hole 18 Connection hole 20 Air passage (main air passage)
21 Airway (branch airway)
23 Hollow hole 26 Air passage

Claims (2)

An extrusion mold for molding a molded body having a plurality of hollow holes by extruding a molding material,
A support part that divides the flow path of the molding material back and forth, and has a support hole formed with a through hole penetrating in the front-rear direction, and a plurality of protrusions that protrude forward from the support part;
The protrusion is provided with a vent hole penetrating in the flow direction, and the support portion is provided with a ventilation path through which an air flow supplied from the outside flows and communicates with the vent hole of the protrusion,
The support part and the protrusion are connected by an uneven fitting between a connection hole provided on the front side of the support part and a connection part provided at the rear end of the protrusion,
The outer peripheral surface of the connection portion is formed with an outer taper having a smaller outer diameter toward the rear end side, and an inner taper that matches the outer taper is formed on the inner surface of the connection hole. Extrusion mold.   2. The extrusion mold according to claim 1, wherein a taper angle of an outer taper of the connection portion is in a range of 1.0 ° to 5.0 °.

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