JP2010131828A - Bilayer foam molding method and apparatus, and bilayer foam molded article - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bilayer foam molding method capable of infiltrating a second layer part into a gap part mainly between a common mold pressing contact part of a first layer part and a common mold. <P>SOLUTION: In the bilayer foam molding method, the molding of a bilayer foam molded article 31 in which the first layer part 22 and the foaming second layer part 23 are integrated is performed according to: a first layer molding process for performing the molding of the first layer part 22 by using the common mold 24 and a mold 25 for the first layer molding; and a second layer molding process for performing the molding of the foaming second layer part 23 by using the common mold 24 while leaving the molded first layer part 22 as it is and a second layer molding mold 26. Therein, the second layer molding process is performed while forming the gap part 61 between the common mold pressing contact part of the first layer part 22 molded in the first layer molding process and the common mold 24 and, thereby, the second layer part 23 is infiltrated from a marginal part of the first layer part 22 to the gap part 61 and, thereby, an infiltrated part 60 integrated with the second layer part 23 is formed on the marginal part of the common mold pressing contact part of the first layer part 22. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a two-layer foam molding method and apparatus and a two-layer foam molded article.

  Various types of resin molded products are used in vehicles such as automobiles.

  Such a resin molded product 1 includes, for example, an instrument panel 2 as shown in FIG. 7, a lid member such as an airbag grid, other molded parts, and the like. Here, the instrument panel 2 is a vehicle interior front panel provided at the front of the vehicle interior.

  The instrument panel 2 has a three-layer structure having a core material 3, a foam layer 4, and a skin layer 5 in order from the back surface side.

  The instrument panel 2 having a three-layer structure is usually manufactured as follows.

  That is, first, the core material 3 is injection-molded using a core material molding apparatus 6 such as an injection molding apparatus (core material molding step 7). Separately, the skin layer 5 is powder slush molded or vacuum molded using a skin layer molding apparatus 8 such as a powder slush molding apparatus or a vacuum molding apparatus (skin layer molding step 9).

  Next, foaming pretreatment such as seal tape treatment and primer treatment is performed on the obtained core material 3 and the skin layer 5 (foaming pretreatment step 11). This foaming pretreatment is mainly performed in order to prevent leakage of a foaming agent (chemical solution) described later. When the preparation is completed, the core material 3 and the skin layer 5 are set in a foam molding apparatus (foam layer molding apparatus 12), and a foaming agent is injected between the core material 3 and the skin layer 5, Foaming (instrument panel forming step 13). Thereby, the foam layer 4 is formed (foam molding) between the core material 3 and the skin layer 5, and the instrument panel having a three-layer structure in which the core material 3, the foam layer 4 and the skin layer 5 are integrated. 2 is molded.

  Finally, excess portions such as product terminal portions and openings are trimmed as a post-foaming process for the obtained instrument panel 2 (foaming post-processing step 14). Thus, the instrument panel 2 is completed.

  Thus, when the foam layer 4 is formed after the core material 3 and the skin layer 5 are separately molded, a plurality of different molding devices (core material molding device 6, skin layer molding device 8, foaming) are formed. There is a problem that the layer forming apparatus 12) is required, and the equipment cost, production cost, production time and the like are increased. In addition, there is a problem that it takes time to perform pre-foaming treatment and post-foaming treatment.

  Therefore, in recent years, by combining two-color molding technology and injection foam molding technology, a single injection molding device is used to mold a hard core material and a soft skin layer having foamability. Research on so-called two-layer foam molding has been conducted (see, for example, Patent Document 1).

  Here, the injection foam molding is to inject a resin raw material mixed with foaming gas into a mold and foam the mold in the mold. In injection foam molding, the mold is core-backed (slightly opened) after the resin raw material mixed with the foaming gas is injected until the resin raw material is cured. Since the inside of the mold is depressurized and the foaming gas in the resin expands, the resin raw material can be expanded to the target plate thickness. In addition, general-purpose resin, a thermoplastic elastomer, etc. are used for the resin raw material. As the foaming gas, a chemical foaming agent (chemical) such as baking soda or a gas (physical) such as N2 or CO2 is used. The foaming gas is mixed at the time of plasticizing the resin raw material, for example.

  The above-described two-layer foam molding is more specifically as follows.

  As shown in FIGS. 8A to 8D, first, as the two-layer foam molding apparatus 21, the first layer portion 22 (core material, see FIG. 8A) and the second layer portion 23 (skin layer, see FIG. 8C) are formed. A common mold 24 that can be used for molding, a first-layer molding mold 25 that can be used for molding the first layer portion 22, and a second-layer molding die 26 that can be used for molding the second layer portion 23. prepare. The second-layer molding die 26 is configured such that the inside (molding space) is slightly larger than the first-layer molding die 25.

  In this case, the shared mold 24 is a movable mold and a core mold having a convex molding surface 27. The first-layer molding die 25 and the second-layer molding die 26 are fixed cavities and cavity molds having concave molding surfaces 28 and 29, respectively.

  The first-layer molding die 25 and the second-layer molding die 26 are disposed adjacent to each other (in this case, left and right). The common mold 24 is different from the first-layer molding mold 25 and the second-layer molding mold 26 by sliding (in this case, in the left-right direction) and (in this case, in the horizontal direction (front-rear) It is configured so that mold clamping and mold opening can be performed by proximity and separation of the direction).

  In the above-described two-layer foam molding apparatus 21 shown in FIG. 8, the mold has a so-called one-core two-cavity type that includes one core mold and two cavity molds.

  However, the mold configuration of the two-layer foam molding apparatus 21 is not limited to this. For example, a so-called two-core two-cavity type having two core molds and two cavity molds may be used. Moreover, it is good also as what is called a 1 core 1 cavity type provided with one core type | mold and one cavity type | mold.

  Further, as shown in FIG. 8, the shared mold 24 has an ejector pin 33 that can remove the molded two-layer foam molded product 31 (for example, a resin molded product such as an instrument panel, see FIG. 9). It is provided as a product protruding device. In this case, the ejecting direction of the ejector pin 33 (product projecting direction, mold releasing direction) is set to be the same as the mold opening / closing direction 34.

  A first layer injection machine 35 capable of injecting and injecting a general-purpose resin such as PP is attached to the first-layer molding die 25. The second layer molding die 26 is provided with a second layer injection machine 36 that can inject and inject a foaming gas into a thermoplastic elastomer or the like.

  In order to prevent leakage of the thermoplastic elastomer as the second layer molding resin material when the common mold 24 is core-backed to the second layer molding die 26, at least the second layer The molding die 26 is provided with an outer fitting portion 37 (seal structure portion) that can be fitted to the outer peripheral portion of the shared die 24 in a sliding contact state in the mold opening / closing direction 34.

  And when molding the two-layer foam molded article 31, as shown in FIG. 8A, in the first layer molding step, the hard first layer portion 22 is formed using the shared mold 24 and the first-layer molding mold 25. Perform molding.

  That is, the shared mold 24 and the first-layer molding mold 25 are clamped, and the first layer injection machine 35 enters the mold (the molding space between the shared mold 24 and the first-layer molding mold 25). The first layer portion 22 is molded by injecting a general-purpose resin such as PP as a single layer molding resin material (core material molding resin material).

  Thereafter, as shown in FIG. 8B, the two-layer foam molding apparatus 21 is once opened, and the first-layer molding mold 25 is replaced with a second-layer molding mold 26 that can be used for molding the second layer portion 23. (Mold exchange step. In this case, the shared mold 24 is slid to the second layer forming mold 26 side (left side)).

  Next, as shown in FIG. 8C, in the second layer forming step, a foamable (soft) is formed by using the shared mold 24 and the second layer forming mold 26 while leaving the molded first layer portion 22 left. The second layer portion 23 is molded.

  That is, the shared mold 24 and the second-layer molding mold 26 are clamped, and the inside of the mold (the molding space between the shared mold 24 (including the first layer portion 22) and the second-layer molding mold 26). The second layer portion 23 is molded by injecting a thermoplastic elastomer mixed with foaming gas from the second layer injection machine 36 as a second layer molding resin raw material (skin layer molding resin raw material). To do.

  At this time, although not particularly illustrated, the second layer molding resin raw material is a surface layer having a relatively high density because the portion in contact with the second layer molding die 26 is hardened first without being foamed. Part 38 is formed. Other uncured second layer molding resin materials are cured while foaming.

  Then, as shown in FIG. 8D, the shared mold 24 is core-backed against the second-layer molding die 26 while the uncured second-layer molding resin material is being foamed and cured (slightly The mold is opened (core back process).

  Then, since the inside of the mold is depressurized and the foaming gas in the thermoplastic elastomer expands, the uncured portion of the resin raw material for second layer molding fills the portion of the space expanded by the core back of the molding space. Swells at once.

  Accordingly, as shown in FIG. 9, a two-layer foam molded product 31 (for example, an instrument panel) in which the first layer portion 22 and the foamable second layer portion 23 are integrated can be molded. .

  At this time, as described above, at least the surface layer portion 38 having a relatively high density and the intermediate layer portion 39 having a relatively low density are formed in the second layer portion 23 after curing (that is, the inside is Substantially multi-layered). However, there is no clear boundary line between the surface layer portion 38 and the intermediate layer portion 39 (note that the boundary line may be described in the drawing for convenience of expression). Here, the ratio of the thickness between the surface layer portion 38 and the intermediate layer portion 39, the foaming rate, and the like can be set or adjusted to some extent depending on the amount and timing of the core back.

  Although not particularly shown in FIG. 8, in the demolding process, by performing demolding using a product projecting device such as the ejector pin 33, a configuration almost equivalent to the above-described three-layered instrument panel 2. It is possible to obtain a two-layer foamed molded article 31 such as an instrument panel having

  More specifically, for example, in the case of molding a two-layer foam molded product 31 (see FIG. 11D) having the first layer portion 22 (core material) as shown in FIG. A two-layer foam molding apparatus 21 as shown will be used.

  Here, the first layer portion 22 of FIG. 10 will be described. The first layer portion 22 mainly has a flat surface portion 41. Openings 42 and 43 are formed inside the flat surface portion 41. In this case, the surface portion 41 has a rectangular shape, and two openings 42 and 43 are formed, and each has a rectangular shape and a circular shape. A flange portion 44 is formed on the outer peripheral edge portion of the flat surface portion 41.

  On the other hand, the opening edge portion of the rectangular opening portion 42 is a flat edge portion 45 that does not have an out-of-plane protruding portion with respect to the flat surface portion 41. A flange 46 is formed at the opening edge of the circular opening 43. The flange portion 44 at the outer peripheral edge of the flat surface portion 41 includes a surface straight flange portion 47 that is substantially straight with respect to the flat surface portion 41 and an inclined flange portion 48 that is inclined with respect to the flat surface portion 41. Has been. Further, the flange 46 at the opening edge of the opening 43 is a straight flange 47.

  On the other hand, in the two-layer foam molding apparatus 21 as shown in FIG. 11 (to FIG. 13), on the molding surface 27 of the shared mold 24, as shown in FIG. A portion 55 is provided. Among them, the flange surface molding portion 51 corresponds to the flange surface 44 a of the flange portion 44 (the surface straight flange portion 47 and the inclined flange portion 48 (see FIG. 11A)) of the first layer portion 22. The flange surface molding part 51 includes a straight flange surface molding part 52 and an inclined flange surface molding part 53 (see FIG. 11A). Further, the flange end surface molding portion 55 corresponds to the end surface 44b of the flange portion 44 of the first layer portion 22 and the end surface 54a (see FIG. 12B) of the flange surrounding portion 54 of the second layer portion 23. .

  The flange surrounding portion 54 of the second layer portion 23 covers the flange portion 44 (the side surface portion) of the first layer portion 22. The end surface 44b of the flange portion 44 of the first layer portion 22 and the end surface 54a of the flange surrounding portion 54 of the second layer portion 23 are formed flush with each other.

  Further, as shown in FIG. 13, a flat surface molding portion 57 is provided on the molding surface 27 of the shared mold 24. The flat surface molding portion 57 corresponds to the edge back surface 45 a of the flat edge 45 of the first layer portion 22 and the end surface portion 56 a of the end surface surrounding portion 56 of the second layer portion 23. The end surface surrounding portion 56 of the second layer portion 23 covers the end surface of the flat edge 45 of the first layer portion 22. Further, the edge back surface 45 a of the flat edge 45 of the first layer portion 22 and the end surface portion 56 a of the end surface surrounding portion 56 of the second layer portion 23 are formed flush with each other.

  The back surface of the first layer portion 22 is a shared mold contact portion that contacts the molding surface 27 of the shared mold 24. Further, the flange surface 44 a and the end surface 44 b of the flange portion 44 described above and the edge rear surface 45 a of the flat edge portion 45 are edges of the shared contact portion of the first layer portion 22.

  Here, FIG. 11A is a first layer forming step, FIG. 11B is a second layer forming step, FIG. 11C is a core back step, and FIG. 11D is a demolding step. 12A and 13A show the first layer forming step, and FIGS. 12B and 13B show the second layer forming step. In addition, about the type | mold exchange process, illustration is abbreviate | omitted.

On the other hand, in addition to the two-layer foam molding apparatus 21, it is possible to simplify the foam pretreatment in the manufacture of the instrument panel 2 having the three-layer structure described above. There is also known a structure in which a flexible seal member made of rubber formed separately is attached and leakage of the foaming agent can be prevented by this seal member (for example, see Patent Document 2).
Patent No. 3118125 JP 2006-68914 A

  However, the above-described two-layer foam molding has the following problems.

  That is, as shown in FIGS. 12 (a) and 13 (a), the first layer portion 22 formed in the first layer forming step is left as shown in FIGS. 12 (b) and 13 (b). As described above, since the second layer portion 23 is formed in the second layer forming step, the first layer portion 22 (the inner surface portion thereof, etc.) remains as it is when the second layer portion 23 is formed. It will be used as a molding surface for the shared mold 24. Therefore, the second layer molding resin is provided between the shared mold 24 and the edge (flange surface 44a, end surface 44b, edge back surface 45a, etc.) of the shared contact portion (back surface) of the first layer portion 22. It has been difficult to wrap around the raw material (thermoplastic elastomer mixed with foaming gas).

  Therefore, in the obtained two-layer foam molded product 31 (for example, an instrument panel), the edge of the shared contact portion of the first layer portion 22 is exposed, and the appearance quality is deteriorated, or peripheral components are exposed. There is a risk of problems in combination with the. Along with this, there is a possibility that a low-priced sound may be generated due to contact or rubbing between the edge of the shared contact portion of the first layer portion 22 and the peripheral parts.

  In addition to the above, new problems and other problems may occur in the process leading to the present invention. Such new problems and other problems will be described in the embodiments of the present invention instead of being described in this section. However, when it becomes necessary to describe in this column, the description in the examples can be added to this column. In that case, it is possible to correct the expression suitable for the description in this column.

  In order to solve the above problems, the invention described in claim 1 includes a first layer molding step of molding a first layer portion using a shared mold and a first-layer mold, and a molded first The first layer portion and the second layer portion are formed by the second layer forming step of forming the foamable second layer portion using the common mold with the layer portion remaining and the second layer forming die. In the two-layer foam molding method for molding an integrated two-layer foam molded product, a gap is formed between the shared mold contact portion and the shared mold of the first layer portion molded in the first layer molding step. By performing the second layer forming step in the formed state, the second layer portion is circulated from the edge portion of the first layer portion to the gap portion, and the second layer portion is moved to the edge portion of the shared contact portion of the first layer portion. It is characterized by forming a wraparound portion integral with the two-layer portion.

  The invention described in claim 2 is such that, in the above, the gap portion between the shared mold abutting portion and the shared mold of the first layer portion formed in the first layer forming step is blocked in the middle. By performing the second layer forming step in this state, it is possible to prevent the second layer portion that has entered the gap portion from being excessively expanded in the gap portion.

  The invention described in claim 3 is a common mold that can be used for molding the first layer portion and the foamable second layer portion, and a first-layer molding die that can be used for molding the first layer portion. And a second layer molding die that can be used for molding the second layer portion, and a two-layer foam molded product in which the first layer portion and the second layer portion are integrated is configured to be moldable. In the layer foam molding apparatus, the second layer portion is moved from the edge of the first layer portion to the clearance portion by forming a gap portion between the shared mold contact portion and the shared mold of the molded first layer portion. It is characterized in that a common part is provided with a gap forming mechanism capable of forming a wrapping part integral with the second layer part at the edge of the common type contact part of the first layer part.

  In the invention described in claim 4, in the above, in the gap portion between the shared mold contact portion and the shared mold of the molded first layer portion, the second layer portion that goes around the gap portion is in the middle. It is characterized by providing a damming portion that can dam and prevent the second layer portion from spreading too much in the gap.

  According to a fifth aspect of the present invention, in the above, the gap portion forming mechanism controls the size of the gap portion by controlling an ejector pin from which the two-layer foam molded product can be removed and a protruding length of the ejector pin. It has an ejector pin control mechanism that can be freely set and adjusted.

  According to a sixth aspect of the present invention, in the above, the ejector pin includes a deformation prevention shape portion at a tip portion thereof, and the deformation prevention shape portion has a first layer portion as a gap portion is formed. It is characterized by being able to suppress and prevent deformation.

  According to a seventh aspect of the present invention, in the above, the ejector pin includes a first layer partial levitation prevention mechanism portion, and the first layer partial levitation prevention mechanism portion circulates into the gap portion. Thus, it is possible to prevent the first layer portion from floating during the molding of the second layer portion.

  According to an eighth aspect of the present invention, in the above, the damming portion is a protrusion-shaped portion integrally formed on the first layer portion by a damming portion forming concave portion formed in a shared mold, and the protrusion The shape portion is configured to protrude from the first layer portion in the gap portion forming direction and to have a protruding amount larger than that of the gap portion.

  According to a ninth aspect of the present invention, in the above, the damming portion forming concave portion and the projecting shape portion have a seal surface that is substantially perpendicular to the gap portion forming direction on the outer side surface, and the inner side surface. It is characterized by having an anti-corrosion taper surface that is tapered at the portion.

  According to a tenth aspect of the present invention, there is provided a two-layer foam molded product in which a first layer portion and a foamable second layer portion are integrated, wherein the second layer portion is a shared mold of the first layer portion. It is characterized by integrally having a wraparound portion that wraps around the edge of the contact portion.

  Each of the above is the minimum necessary configuration for exhibiting the required operational effects. Of course, details of the above configuration and configurations not described above have a degree of freedom. is there. Of course, matters that can be read from the description of the above configuration are included in the scope even if they are not specifically described. In addition, when a configuration other than the above is added, it is needless to say that the operational effects of the added configuration are added.

  According to invention of Claim 1, the following effects can be acquired by the said structure. That is, a first layer molding step for molding the first layer portion using the shared mold and the first layer molding die, and the shared mold and the second layer molding die with the molded first layer portion remaining. And forming a two-layer foam molded product in which the first layer portion and the second layer portion are integrated by sequentially performing a second layer forming step of forming a foamable second layer portion using To do. And, by forming a gap between the first layer portion molded in the first layer molding step and the shared mold by the gap portion forming mechanism provided in the shared mold, by performing the second layer molding step, The second layer portion is wrapped from the edge portion of the first layer portion to the gap portion, and the wrap portion integrated with the second layer portion is formed at the edge portion of the shared contact portion of the first layer portion. it can. By this wraparound portion, it is possible to prevent the edge of the shared type contact portion of the first layer portion of the two-layer foam molded product from being exposed. As a result, it is possible to prevent the appearance quality from being deteriorated due to the exposed edge of the shared contact portion of the first layer portion. In addition, by interposing the flexible wrapping portion, it is possible to prevent problems on the combination between the edge of the shared contact portion of the first layer portion and the peripheral parts, etc., and the first layer It is possible to prevent the generation of lower sounds due to the contact or rubbing between the edge of the shared contact portion of the part and the peripheral parts.

  According to invention of Claim 2, the following effects can be acquired by the said structure. In other words, by damming the second layer part that has entered the gap part between the shared mold contact part and the shared mold of the first layer part molded in the first layer molding step, An excessive expansion of the second layer portion can be prevented. Thereby, the expansion of the second layer portion can be regulated by the damming portion, and the second layer portion can be controlled to intentionally expand only to the necessary portion of the gap portion.

  According to invention of Claim 3, the following effects can be acquired by the said structure. That is, the first layer portion is molded using the shared mold and the first-layer molding mold, and the shared mold and the second-layer molding mold are left with the molded first layer portion remaining. By forming the second layer portion, a two-layer foam molded product in which the first layer portion and the second layer portion are integrated is manufactured. When forming the second layer portion by forming a gap portion between the shared mold contact portion and the shared mold of the molded first layer portion by the gap portion forming mechanism provided in the shared mold In addition, the second layer portion is wrapped from the edge portion of the first layer portion to the gap portion, and the wrapping portion integral with the second layer portion is formed at the edge portion of the shared contact portion of the first layer portion. be able to. As a result, it is possible to prevent the edge of the shared contact portion of the first layer portion from being exposed. As a result, it is possible to prevent the appearance quality from being deteriorated due to the exposed edge of the shared contact portion of the first layer portion. In addition, by interposing the flexible wrapping portion, it is possible to prevent problems in combination between the first layer portion and the peripheral parts, and the edge of the shared contact portion of the first layer portion. It is possible to prevent the generation of lower sounds due to contact or rubbing between the part and peripheral parts.

  According to invention of Claim 4, the following effects can be acquired by the said structure. That is, the second layer portion that has entered the gap portion is blocked by the damming portion provided in the gap portion between the shared mold contact portion of the molded first layer portion and the shared mold, and the gap It is possible to prevent the second layer portion from being excessively expanded in the portion. Thereby, the expansion of the second layer portion can be regulated by the damming portion, and the second layer portion can be controlled to intentionally expand only to the necessary portion of the gap portion.

  According to the fifth aspect of the present invention, the following operational effects can be obtained by the above configuration. That is, by controlling the protrusion length of the ejector pin using the ejector pin control mechanism, the gap portion can be formed and the size of the gap portion can be freely set and adjusted. Thus, the existing ejector pin can be used effectively for the formation of the gap portion as the gap portion forming mechanism, and the necessity of providing a special gap portion forming mechanism can be eliminated.

  According to invention of Claim 6, the following effects can be acquired by the said structure. That is, it is possible to suppress and prevent the first layer portion from being deformed by the tip portion of the ejector pin as the gap portion is formed by the deformation preventing shape portion provided at the tip portion of the ejector pin. Thereby, generation | occurrence | production of the product malfunction by the deformation | transformation of a 1st layer part can be prevented.

  According to invention of Claim 7, the following effects can be acquired by the said structure. That is, the first layer portion floating prevention mechanism portion provided on the ejector pin prevents the first layer portion from being lifted by the second layer portion that has entered the gap portion during molding of the second layer portion. Can do. Thereby, generation | occurrence | production of the product malfunction by the floating of a 1st layer part can be prevented.

  According to invention of Claim 8, the following effects can be acquired by the said structure. That is, by forming the first layer portion using the shared mold in which the dam portion forming concave portion is formed, the protruding portion integral with the first layer portion as the dam portion is formed on the dam portion forming concave portion. Part can be obtained. And since the dam part is a protrusion-shaped part provided integrally with the first layer part, it is possible to reduce costs and labor for preparing and attaching the dam part separately. Further, by making the damming portion protrude from the first layer portion in the gap portion forming direction to be larger than the gap portion, the damming portion is completely removed from the damming portion forming recess and does not function. This can be prevented. That is, when the dam part is pulled out from the dam part forming concave part to form the gap part, the dam part can be surely functioned.

  According to invention of Claim 9, the following effects can be acquired by the said structure. That is, for forming the gap portion and the dam portion by forming the gap portion by a seal surface that is substantially in the direction of the gap portion formed in the outer surface portion of the dam portion forming concave portion and the protruding portion. Sealability between the recesses can be ensured. Further, the tapering surface for anti-corrosion provided on the inner side surface of the damming portion forming concave portion and the projecting shape portion provides a taper between the damming portion and the damming portion molding concave portion when forming the gap portion. It is possible to prevent the biting between. Thereby, the blocking part which functions effectively can be obtained.

  According to the invention of claim 10, the same effect as that of claim 1 or claim 3 can be obtained by the above configuration.

  An object of the present invention is mainly to enable the second layer portion to go around in the gap portion between the shared type contact portion and the shared type of the first layer portion.

  Hereinafter, embodiments embodying the present invention will be described together with illustrated examples.

  The following examples have a close relationship with the above-described background art and problems to be solved by the invention. Therefore, when necessary, the descriptions are diverted to each other or necessary corrections are made. And can be diverted.

  1 to 6 show an embodiment of the present invention and a modification thereof.

  8 to 13 described above and the description on these drawings are basically the same in this embodiment as well, and therefore the description is omitted to prevent the specification from being redundant. . Therefore, for the omitted parts, the above-described drawings and description are referred to as necessary. However, portions different in configuration from this embodiment are not referred to. That is, priority is given to FIGS. If necessary, the description of the omitted part can be added to this column. For this reason, the same or equivalent parts as in FIGS. 8 to 13 are given the same reference numerals to clarify the correspondence with them so that no doubt arises.

  <Configuration> First, the configuration will be described.

  A first layer molding step (see FIG. 1A) for molding the first layer portion 22 using the shared mold 24 and the first-layer molding die 25, and the first layer portion 22 molded in the first layer molding step. A second layer molding step for molding the foamable second layer portion 23 using the shared mold 24 as it is and the second layer molding die 26 (replaced with the first layer molding die 25). 1C), the two-layer foam molded product 31 in which the first layer portion 22 and the foamable second layer portion 23 are integrated can be molded (see FIG. 1D). In such a two-layer foam molding method, the following configuration is provided.

  (1) As shown in FIG. 1B, between the shared mold contact portion (contact surface with the shared mold 24) of the first layer portion 22 formed in the first layer molding step of FIG. 1A and the shared mold 24. In the state where the gap portion 61 is formed, the second layer portion from the edge (outer peripheral edge portion or opening edge portion) of the first layer portion 22 to the gap portion 61 is performed by performing the second layer forming step of FIG. 1C. 23, and the wrapping portion integral with the second layer portion 23 at the edge of the shared contact portion (back surface) of the first layer portion 22 (such as the back surface of the outer peripheral edge or the back surface of the opening edge). 60 is formed.

  Here, as described above, the edge portion of the shared contact portion of the first layer portion 22 is more specifically the flange surface 44a and the end surface 44b of the flange portion 44 and the edge portion of the flat edge portion 45. For example, the back surface 45a. The gap 61 is formed by floating the first layer portion 22 as a whole with respect to the shared mold 24. The clearance 61 may be of a size that allows the second layer portion 23 to go around. Specifically, the gap portion 61 is assumed to be uniform over almost the whole of about 1 mm to 2 mm. The wraparound portion 60 is illustrated as the second layer portion 23 that has entered the gap portion 61.

  (2) In the above, with the gap portion 61 between the shared mold contact portion of the first layer portion 22 molded in the first layer molding step and the shared mold 24 being able to be dammed in the middle, By performing the second layer forming step of FIG. 1C, it is possible to prevent the second layer portion 23 that has entered the gap portion 61 from being excessively expanded in the gap portion 61.

  That is, the second layer portion 23 can be intentionally expanded only to a necessary portion in the gap portion 61. Note that means (such as the damming portion 63) for preventing the second layer portion 23 that has turned around from being excessively expanded will be described later.

  And as a device configuration for carrying out the above method, the shared mold 24 that can be used for the molding of the first layer portion 22 and the foamable second layer portion 23 and the molding of the first layer portion 22 are used. A first layer comprising a possible first-layer mold 25 (mainly see FIG. 1A) and a second-layer mold 26 (mainly see FIG. 1C) that can be used to form the second layer portion 23; A two-layer foam molding apparatus 21 configured to mold a two-layer foam molded product 31 (mainly see FIG. 1D) in which the portion 22 and the foamable second layer portion 23 are integrated is used. Such a two-layer foam molding apparatus 21 has the following configuration.

  (3) As shown in FIG. 1B, by forming a gap portion 61 between the shared mold contact portion of the molded first layer portion 22 and the shared mold 24, from the edge of the first layer portion 22. Gap portion forming mechanism capable of forming the wrap portion 60 integral with the second layer portion 23 at the edge of the shared contact portion of the first layer portion 22 by causing the second layer portion 23 to wrap around the gap portion 61. 62 (see FIG. 2) is provided in the shared type 24.

  (4) In the above, as shown in FIG. 4, the second layer wraps around the gap 61 in the gap 61 between the shared mold contact portion of the molded first layer portion 22 and the shared mold 24. The part 23 is dammed in the middle, and a dam part 63 that can prevent the second layer part 23 from spreading too much in the gap 61 is provided.

  That is, the expansion of the second layer portion 23 in the gap 61 can be regulated by the blocking portion 63. By such a damming portion 63, the above-described wraparound portion 60 is formed with respect to a portion of the gap portion 61 until it is dammed by the damming portion 63. The dam member 63 is preferably capable of restricting the expansion of the second layer portion 23 to the edge of the shared contact portion of the first layer portion 22. Therefore, it is preferable that the damming portion 63 is provided at a position at a substantially constant distance from the edge of the first layer portion 22 (such as the outer peripheral edge and the opening edge).

  (5) In the above, as shown in FIG. 2 or 3, the gap portion forming mechanism 62 controls the ejector pin 33 from which the two-layer foam molded product 31 can be removed and the protrusion length of the ejector pin 33. An ejector pin control mechanism 64 that can freely set and adjust the size of the gap 61 is provided.

  That is, the ejector pin control mechanism 64 is used to project the ejector pin 33 by a small amount so that the first layer portion 22 can be lifted slightly.

  Here, with respect to the first layer portion 22, the ejector pin 33 is provided in a portion inside the dam portion 63 (a portion away from the edge portion of the first layer portion 22). The ejector pin control mechanism 64 can be provided for the drive device 65 that drives the ejector pin 33 or the like. The ejector pin control mechanism 64 may be mechanical or electrical.

  (6) In the above, as shown in FIG. 5, the ejector pin 33 can be provided with a deformation preventing shape portion 66 at the tip thereof. The deformation preventing shape portion 66 is configured to be capable of suppressing and preventing the first layer portion 22 from being deformed in association with the formation of the gap portion 61.

  Here, the deformation preventing shape portion 66 may be, for example, a block-shaped contact area expanding portion provided at the tip of the ejector pin 33. Correspondingly, the pin hole 67 of the ejector pin 33 provided in the shared mold 24 also includes an enlarged shape portion 68 having a shape and a size capable of accommodating the deformation prevention shape portion 66 in the opening portion on the molding surface 27 side. To.

  Note that the deformation preventing shape portion 66 (contact area expanding portion or the like) deforms or damages the first layer portion 22 when the surface contacting the first layer portion 22 is lifted by the ejector pin 33. The size is such that it can be suppressed and prevented, and that the deformation and damage of the first layer portion 22 due to the injection pressure and foaming pressure of the second layer portion 23 can be suppressed and prevented.

  (7) In the above, as shown in FIG. 5, the ejector pin 33 can include a first layer partial levitation preventing mechanism 71. The first layer portion levitation preventing mechanism 71 is configured to prevent the first layer portion 22 from being lifted during the molding of the second layer portion 23 by the second layer portion 23 that has entered the gap portion 61. Composed.

  Here, the first layer partial levitation preventing mechanism 71 is provided at the tip of the ejector pin 33. The first layer partial levitation prevention mechanism 71 is configured to be able to prevent the first layer portion 22 from being lifted by being locked to the first layer portion 22.

  For example, the first layer partial levitation preventing mechanism 71 may be, for example, a so-called Z-type ejector pin 73 having a Z-shaped portion 72 formed by cutting out the tip of the ejector pin 33 in a substantially Z shape. The Z-type ejector pin 73 is formed integrally with the first layer portion 22 in the pin hole 67 by forming the first layer portion 22 with the Z-shaped portion 72 slightly retracted from the pin hole 67. By forming the protruding portion 74 and allowing the protruding portion 74 having the same size (diameter dimension) as the pin hole 67 to be locked and held by the Z-shaped portion 72 at the tip, the first layer portion 22 is formed. It is intended to prevent the lifting of. Also, by providing a Z-shaped portion 72 at the tip of the ejector pin 33 without enlarging the cross section, the Z-shaped portion 72 and the projecting portion 74 can be unlocked and removed by force. It is. In other words, the first layer portion 22 can be prevented from being lifted by engaging with a force that can be forcibly removed.

  Further, the first layer partial levitation preventing mechanism 71 has, for example, a locking portion 75 projecting laterally from the tip of the ejector pin 33, and the ejector pin 33 is inclined with respect to the mold opening / closing direction 34 as a whole. In addition, a so-called inclined pin 76 can be used. The inclined pin 76 is formed integrally with the first layer portion 22 in the locked portion forming space 77 provided in the opening portion of the pin hole 67 on the molding surface 27 side by molding the first layer portion 22. It is possible to prevent the first layer portion 22 from being lifted by allowing the formed locked portion 78 having a substantially L shape in side view to be locked and held by the locking portion 75 at the tip. It is a thing. In addition, the ejector pin 33 and the pin hole 67 are inclined so that the ejector pin 33 protrudes, so that the locking portion 75 is shifted laterally with respect to the locked portion 78, and the ejector pin 33 is When fully projected, the engaged state between the locked portion 78 and the locking portion 75 is released so that the mold can be removed. That is, by engaging the locked portion 78 and the locking portion 75 relatively firmly, it is possible to prevent the first layer portion 22 from being lifted, and automatically engages when the mold is removed. It can be released. In order to form the locked portion 78, the locked portion forming space 77 is formed to be slightly larger than the locking portion 75. Further, the inclined pin 76 is pivotally supported at its base end portion (in this case, the lower end portion) so as to be rotatable.

  The Z-type ejector pin 73 and the inclined pin 76 described above serve as the deformation preventing shape portion 66 by supporting the first layer portion 22 from the lower side in the figure via the protruding portion 74 and the locked portion 78. It can have a function (somewhat). In particular, in the case of the inclined pin 76, the locking portion 75 at the tip can also function as a contact area expanding portion or the like, and thus also serves as the deformation preventing shape portion 66.

  (8) In the above, as shown in FIG. 4, the blocking portion 63 is formed by the protruding portion 82 integrally formed on the first layer portion 22 by the blocking portion forming recess 81 formed in the shared mold 24. To do. The protruding portion 82 is configured to protrude from the first layer portion 22 in the gap portion forming direction and to have a larger protruding amount than the gap portion 61.

  In this case, the gap portion forming direction is set to be the same direction as the mold opening / closing direction 34.

  (9) In the above, the blocking portion forming concave portion 81 and the projecting shape portion 82 have the seal surfaces 83 and 84 that are substantially perpendicular to the gap portion forming direction on the outer surface portion, and are tapered on the inner surface portion. It shall have the taper surfaces 85 and 86 for anti-corrosion.

  In addition, an outer surface part means the side from which the 2nd layer part 23 wraps around.

  Moreover, the above-described damming portion 63 (setting damming portion) is specially set. On the other hand, in the case where the flange portion 46 described above is the surface straight flange portion 47, the flange surface 44a and the flange surface molding portion 51 have a function as a seal surface, so that the blocking portion provided on the mold structure. 63 (non-setting damming portion). In this case, the special damming portion 63 described above may not be provided (of course, the damming portion 63 may be provided).

  Further, even if the flange portion 46 described above is the inclined flange portion 48, when the amount of inclination of the inclined flange portion 48 is so small as to be negligible, the blocking portion 63 (seal surface) is used. Since it can have a function, it can be called the damming part 63 (non-setting damming part) as described above.

  For example, in the case of the first layer portion 22 (core material) in FIG. 10, as shown in FIG. 6, the damming portion 63 (the protruding portion 82) is mainly flat of the first layer portion 22. It is provided around the openings 42 and 43 on the molding surface 27 side (shared-type contact portion side) of the surface portion 41 so as to surround the entire circumference in a state slightly separated from the opening edge.

  Further, although not particularly shown in FIG. 6, the damming portion 63 (the projecting shape portion 82) is on the molding surface 27 side (common type contact portion side) of the flat surface portion 41 of the first layer portion 22. It may be provided around the flange portion 44 so as to surround the entire circumference in a state slightly separated from the flange portion 44 inward.

  (10) In the two-layer foam-molded article 31 in which the first layer portion 22 and the foamable second layer portion 23 are integrated, the second layer portion 23 is the first layer using the method and apparatus described above. A two-layer foam molded product 31 integrally having a wrapping portion 60 that wraps around the edge of the shared type contact portion of the portion 22 is formed.

  <Operation> Next, the operation of this embodiment will be described.

  First, the first layer forming step is performed in FIG. 1A. Next, a mold exchange process is performed. Then, the second layer forming step is performed in FIG. 1C, and then the core back step is performed in FIG. 1D. Finally, a demolding process is performed in FIG. 1E. Thus, a two-layer foam molded article 31 (for example, an instrument panel) in which the first layer portion 22 and the foamable second layer portion 23 are integrated is obtained. In addition, about these, further description is abbreviate | omitted.

  In this embodiment, the core material (slightly) projecting step of FIG. 1B is performed between the first layer forming step of FIG. 1A and the second layer forming step of FIG. 1C. In this case, the core material protruding step is performed after the mold opening in the first layer forming step and before the die replacement. And thereby, the 2nd layer part 23 is made to obtain the two-layer foaming molded product 31 which went around to the edge of the shared type contact part of the 1st layer part 22. FIG.

  According to this embodiment, the following operational effects can be obtained.

  (1) A first layer molding step for molding the first layer portion 22 using the shared mold 24 and the first-layer molding die 25, and a first layer portion 22 molded (in the first layer molding step). The first layer portion 22 and the foamable second layer are formed by the second layer molding step in which the foamable second layer portion 23 is molded using the shared mold 24 and the second-layer molding die 26 left as they are. In the two-layer foam molding method for molding a two-layer foam molded product 31 in which the layer portion 23 is integrated, the shared mold contact portion and the shared mold 24 of the first layer portion 22 molded in the first layer molding step. Between the edges (outer peripheral edge and opening edge) of the first layer portion 22 by performing the second layer forming step with the gap portion 61 (required or slight) formed between The second layer portion 23 wraps around the gap portion 61, and the edge of the shared contact portion of the first layer portion 22 (the back surface of the outer peripheral edge portion or the opening edge portion) By forming a sneak portion 60 integral with the second layer portion 23 to the face, etc.), it is possible to obtain the following effects.

  That is, the first layer forming step of forming the first layer portion 22 using the shared mold 24 and the first-layer forming mold 25, and the shared mold 24 and the second mold with the formed first layer portion 22 remaining. The first layer portion 22 and the foamable second layer portion 23 are obtained by sequentially performing the second layer molding step of molding the foamable second layer portion 23 using the layer molding die 26. The integrated two-layer foam molded product 31 is molded.

  And the clearance gap formation mechanism 62 provided in the shared mold 24 forms the clearance gap 61 between the 1st layer part 22 shape | molded by the 1st layer shaping | molding process, and the shared mold 24, The 2nd layer shaping | molding process By performing the above operation, the second layer portion 23 is circulated from the edge portion (outer peripheral edge portion or opening edge portion) of the first layer portion 22 to the gap portion 61, and the shared contact portion of the first layer portion 22 is The wrapping portion 60 integral with the second layer portion 23 can be formed on the edge (the back surface of the outer peripheral edge portion, the back surface of the opening edge portion, or the like). By this wrapping portion 60, it is possible to prevent the edge of the shared type contact portion (the back surface of the outer peripheral edge portion or the back surface of the opening edge portion) of the first layer portion 22 of the two-layer foam molded product 31 from being exposed. . As a result, it is possible to prevent the appearance quality from being deteriorated due to the exposed edge of the shared contact portion of the first layer portion 22 being exposed. In addition, by interposing the flexible wrapping portion 60, it is possible to prevent problems associated with the combination between the edge of the shared contact portion of the first layer portion 22 and the peripheral parts, and the like. It is possible to prevent the generation of lower sounds due to the contact or rubbing between the edge of the shared contact portion of the one-layer portion 22 and the peripheral parts.

  (2) In the above, the gap portion 61 between the shared mold contact portion of the first layer portion 22 formed in the first layer forming step and the shared mold 24 is blocked in the middle. By performing the two-layer molding process, the following effects can be obtained by preventing the second layer portion 23 that has entered the gap portion 61 from being excessively expanded in the gap portion 61. it can.

  That is, by damming the second layer portion 23 that has entered the gap portion 61 between the shared mold contact portion of the first layer portion 22 and the shared mold 24 formed in the first layer molding step, It is possible to prevent the second layer portion 23 from spreading too much in the gap portion 61. Thereby, the expansion of the second layer portion 23 is restricted by the blocking portion 63, and the second layer portion 23 is intentionally expanded only to the necessary portion of the gap portion 61 (the gap portion 61 of the second layer portion 23). To prevent the spread to the whole and the spread to the unnecessary part).

  (3) a common mold 24 that can be used for molding the first layer portion 22 and the foamable second layer portion 23; a first-layer molding die 25 that can be used for molding the first layer portion 22; A two-layer foam molded product 31 comprising a second layer molding die 26 that can be used for molding the second layer portion 23 and in which the first layer portion 22 and the foamable second layer portion 23 are integrated. In the two-layer foam molding apparatus 21 configured to be moldable, by forming a gap portion 61 between the shared mold contact portion of the molded first layer portion 22 and the shared mold 24, the first layer portion 22 A gap that allows the second layer portion 23 to wrap around from the edge portion to the gap portion 61 to form a wrapping portion 60 that is integral with the second layer portion 23 at the edge portion of the shared contact portion of the first layer portion 22. By providing the part forming mechanism 62 (see FIG. 2) in the shared type 24, the following operational effects can be obtained.

  That is, the first layer portion 22 is molded using the shared mold 24 and the first-layer molding die 25, and the shared mold 24 and the second-layer molding die 26 with the molded first layer portion 22 remaining. To form a foamable second layer portion 23 (in order), thereby forming a two-layer foam molded product 31 in which the first layer portion 22 and the foamable second layer portion 23 are integrated. Manufacture (molding).

  When forming the second layer portion 23 by forming the gap portion 61 between the molded first layer portion 22 and the shared die 24 by the gap portion forming mechanism 62 provided in the common die 24. Then, the second layer portion 23 is caused to go from the edge of the first layer portion 22 to the gap portion 61, and the edge of the shared contact portion of the first layer portion 22 is integrated with the second layer portion 23. The recessed portion 60 can be formed. Thereby, it is possible to prevent the edge of the shared contact portion of the first layer portion 22 from being exposed. As a result, it is possible to prevent the appearance quality from being deteriorated due to the exposed edge of the shared contact portion of the first layer portion 22 being exposed. In addition, since the flexible wrapping portion 60 is interposed, it is possible to prevent problems in the combination between the first layer portion 22 and the peripheral components, and to share the first layer portion 22 with the common type contact. It is possible to prevent the generation of lower sound due to contact or rubbing between the edge of the part and the peripheral parts.

  (4) In the above, the second layer portion 23 that has entered the gap portion 61 is blocked in the middle of the gap portion 61 between the shared mold contact portion of the molded first layer portion 22 and the shared mold 24. Thus, by providing the blocking portion 63 capable of preventing the second layer portion 23 from being excessively expanded in the gap portion 61, the following operational effects can be obtained.

  That is, the second layer portion 23 that has entered the gap portion 61 is halfway through the dam portion 63 provided in the gap portion 61 between the shared mold contact portion of the molded first layer portion 22 and the shared mold 24. It is possible to prevent the second layer portion 23 from spreading too much in the gap portion 61. Thereby, the expansion of the second layer portion 23 is restricted by the blocking portion 63, and the second layer portion 23 is intentionally expanded only to the necessary portion of the gap portion 61 (the gap portion 61 of the second layer portion 23). To prevent the spread to the whole and the unnecessary portion).

  (5) In the above, the gap portion forming mechanism 62 freely sets the size of the gap portion 61 by controlling the ejector pin 33 from which the two-layer foam molded product 31 can be removed and the protruding length of the ejector pin 33. By providing the adjustable ejector pin control mechanism 64, the following operational effects can be obtained.

  That is, by controlling the protrusion length of the ejector pin 33 using the ejector pin control mechanism 64, the gap portion 61 can be formed and the size of the gap portion 61 can be freely set and adjusted. Accordingly, the existing ejector pin 33 can be effectively used for the formation of the gap portion 61 as the gap portion forming mechanism 62, and the necessity of providing the special gap portion forming mechanism 62 can be eliminated.

  (6) In the above, the deformation prevention shape portion 66 (the contact surface enlarged shape portion, or the shape of the ejector pin 33 that can suppress and prevent the first layer portion 22 from being deformed as the gap portion 61 is formed) , The block portion) is provided at the tip portion, and the following operational effects can be obtained.

  That is, when the gap portion 61 is formed by the deformation preventing shape portion 66 (contact surface enlarged shape portion or block portion) provided at the distal end portion of the ejector pin 33, the distal end portion of the ejector pin 33 It is possible to suppress or prevent the first layer portion 22 from being deformed. Thereby, generation | occurrence | production of the product malfunction by the deformation | transformation of the 1st layer part 22 can be prevented.

  (7) In the above, the first layer in which the ejector pin 33 can prevent the first layer portion 22 from floating during the molding of the second layer portion 23 due to the second layer portion 23 that has entered the gap portion 61. By providing the partial levitation preventing mechanism 71, the following operational effects can be obtained.

  That is, the first layer portion 22 is lifted by the second layer portion 23 that has entered the gap portion 61 during molding of the second layer portion 23 by the first layer portion floating prevention mechanism portion 71 provided on the ejector pin 33. It can be prevented from going up. Thereby, generation | occurrence | production of the product malfunction by the floating of the 1st layer part 22 can be prevented.

  (8) In the above description, the blocking portion 63 is a protruding portion 82 formed integrally with the first layer portion 22 by the blocking portion forming recess 81 formed in the shared mold 24, and the protruding portion 82. However, by projecting in the gap portion forming direction from the first layer portion 22 and having a larger projection amount than the gap portion 61, the following operational effects can be obtained.

  That is, by forming the first layer portion 22 using the shared mold 24 in which the dam portion forming concave portion 81 is formed, the first layer portion is formed as the dam portion 63 in the portion of the dam portion forming concave portion 81. 22 can be obtained. And since the dam part 63 is the protrusion-shaped part 82 provided integrally with the 1st layer part 22, the cost and effort which prepare and attach the dam part 63 separately can be reduced. Further, by making the damming portion 63 protrude from the first layer portion 22 in the gap portion forming direction so as to be larger than the gap portion 61, the damming portion 63 is completely removed from the damming portion forming recess 81. It can be prevented that it comes off and does not function. That is, when the dam part 63 is pulled out from the dam part forming concave part 81 to form the gap part 61, the dam part 63 can be reliably functioned.

  (9) In the above, the blocking portion forming concave portion 81 and the projecting shape portion 82 have the seal surfaces 83 and 84 that are substantially perpendicular to the gap portion forming direction on the outer surface portion, and are tapered on the inner surface portion. By having the anti-corrosion tapered surfaces 85 and 86, the following operational effects can be obtained.

  That is, when the clearance 61 is formed by the seal surfaces 83 and 84 that are substantially in the direction of the clearance formed in the outer surface portion of the dam forming recess 81 and the protruding portion 82 (the damming portion). The sealing property between the damming portion 63 and the damming portion molding concave portion 81 when the damming portion 63 is partially pulled out from the molding concave portion 81 can be ensured. Further, when the gap 61 is formed by the tapered anti-corrosion surfaces 85 and 86 provided on the inner surface portions of the damming portion forming concave portion 81 and the protruding portion 82 (the damming portion forming concave portion). It is possible to prevent the biting between the damming portion 63 and the damming portion forming concave portion 81 when the damming portion 63 is partially pulled out from 81. Thereby, the blocking part 63 which functions effectively can be obtained.

  (10) In the two-layer foam-molded article 31 in which the first layer portion 22 and the foamable second layer portion 23 are integrated, the second layer portion 23 is the first layer using the method and apparatus described above. By molding the two-layer foam molded product 31 integrally having the wrapping portion 60 that wraps around the edge of the common type contact portion of the portion 22, the same action as the above (1) or (3) or the like An effect can be obtained.

  Although the embodiments of the present invention have been described in detail with reference to the drawings, the embodiments are only examples of the present invention, and the present invention is not limited to the configurations of the embodiments. Needless to say, design changes and the like within a range not departing from the gist of the invention are included in the present invention. Further, for example, when each embodiment includes a plurality of configurations, it is a matter of course that possible combinations of these configurations are included even if not specifically described. Further, when a plurality of embodiments and modifications are shown, it is needless to say that possible combinations of configurations extending over these are included even if not specifically described. Further, the configuration depicted in the drawings is of course included even if not particularly described. Further, when there is a term of “etc.”, it is used in the sense that the equivalent is included. In addition, when there are terms such as “almost”, “about”, “degree”, etc., they are used in the sense that they include those in the range and accuracy recognized by common sense.

It is side sectional drawing which shows the 1st layer shaping | molding process concerning the two-layer foam molding apparatus of the Example of this invention. It is side sectional drawing which shows a core material protrusion process. It is side sectional drawing which shows a 2nd layer shaping | molding process. It is side sectional drawing which shows a core back process. It is side sectional drawing which shows a demolding process. (A) is an enlarged view of the flange part of a 1st layer shaping | molding process, (b) is an enlarged view of the flange part of a 2nd layer shaping | molding process. (A) is an enlarged view of the flat edge part of a 1st layer shaping | molding process, (b) is an enlarged view of the flat edge part of a 2nd layer shaping | molding process. It is an enlarged view of a dam part. It is side sectional drawing which shows a 1st layer partial levitation prevention mechanism part. (A) is the perspective view which looked at the 1st layer part from the back side, (b) is the back view of the 1st layer part. It is a manufacturing-process figure of the resin molded product concerning a prior art example. It is sectional drawing seen from the shaping | molding apparatus upper part which shows the 1st layer shaping | molding process concerning the conventional 2 layer foam molding apparatus. It is sectional drawing seen from the shaping | molding apparatus upper part which shows a type | mold replacement | exchange process. It is sectional drawing seen from the shaping | molding apparatus upper direction which shows a 2nd layer shaping | molding process. It is sectional drawing seen from the shaping | molding apparatus upper part which shows a core back process. It is sectional drawing of the two-layer foam molded product shape | molded with the two-layer foam molding apparatus. It is the perspective view which looked at the 1st layer part from the front side. It is a sectional side view which shows the 1st layer shaping | molding process concerning the double layer foam molding apparatus using the 1st layer part of FIG. It is side sectional drawing which shows a 2nd layer shaping | molding process. It is side sectional drawing which shows a core back process. It is side sectional drawing which shows a demolding process. (A) is an enlarged view of the flange part of a 1st layer shaping | molding process, (b) is an enlarged view of the flange part of a 2nd layer shaping | molding process. (A) is an enlarged view of the flat edge part of a 1st layer shaping | molding process, (b) is an enlarged view of the flat edge part of a 2nd layer shaping | molding process.

Explanation of symbols

21 Two-layer foam molding apparatus 22 First layer portion 23 Second layer portion 24 Shared mold 25 First layer mold 26 Second layer mold 31 Two layer foam molded product 33 Ejector pin 44a Flange surface (shared mold contact portion) )
44b End face (shared contact part)
45a Edge back (common contact part)
Reference Signs List 60 wrapping portion 61 gap portion 62 gap portion forming mechanism 63 damming portion 64 ejector pin control mechanism 66 deformation prevention shape portion 71 first layer partial levitation prevention mechanism portion 81 recess portion for forming damming portion 82 projecting shape portion 83 seal surface 84 Sealing surface 85 Anti-corrosion taper surface 86 Anti-corrosion taper surface

Claims (10)

A first layer molding step of molding the first layer portion using a shared mold and a first-layer mold;
By the second layer molding step of molding the foamable second layer portion using the shared mold and the second layer molding die while leaving the molded first layer portion,
In the two-layer foam molding method for molding a two-layer foam molded product in which the first layer portion and the second layer portion are integrated,
By performing the second layer molding step in a state where a gap is formed between the shared mold contact portion and the shared mold of the first layer portion molded in the first layer molding step,
The second layer portion is wrapped from the edge portion of the first layer portion to the gap portion, and the wrap portion integrated with the second layer portion is formed at the edge portion of the shared type contact portion of the first layer portion. A two-layer foam molding method characterized.   By performing the second layer molding step in a state where the gap portion between the shared mold contact portion and the shared mold of the first layer portion molded in the first layer molding step can be blocked in the middle, 2. The two-layer foam molding method according to claim 1, wherein the second layer portion that has entered the gap portion can be prevented from over-expanding in the gap portion. A shared mold that can be used for molding of the first layer part and foaming second layer part;
A first-layer mold that can be used to mold the first-layer part;
With a second layer mold that can be used for molding the second layer part,
In the two-layer foam molding apparatus configured to mold a two-layer foam molded product in which the first layer portion and the second layer portion are integrated,
By forming a gap portion between the shared type abutment portion of the molded first layer portion and the shared die, the second layer portion wraps around from the edge of the first layer portion to the gap portion, 2. A two-layer foam molding apparatus characterized in that a gap forming mechanism capable of forming a wraparound portion integral with a second layer portion is provided in an edge portion of a common type contact portion of one layer portion.   In the gap portion between the shared mold contact portion and the shared mold of the molded first layer portion, the second layer portion that wraps around the gap portion is blocked in the middle, and the second layer portion in the gap portion 4. A two-layer foam molding apparatus according to claim 3, further comprising a damming portion capable of preventing overexpansion. The gap forming mechanism is an ejector pin capable of demolding a two-layer foam molded product,
The double-layer foam molding according to claim 3 or 4, further comprising an ejector pin control mechanism capable of freely setting and adjusting the size of the gap portion by controlling the protruding length of the ejector pin. apparatus.   The ejector pin is provided with a deformation preventing shape portion at a tip portion thereof, and the deformation preventing shape portion can suppress and prevent the first layer portion from being deformed in association with the formation of the gap portion. The two-layer foam molding apparatus according to claim 5.   The ejector pin is provided with a first layer partial levitation prevention mechanism portion, and the first layer partial levitation prevention mechanism portion is formed by the second layer portion wrapping around the gap portion during the molding of the second layer portion. The two-layer foam molding apparatus according to claim 5 or 6, wherein the part can be prevented from floating.   The damming portion is a protruding shape portion integrally formed on the first layer portion by a damming portion forming concave portion formed in a shared mold, and the protruding shape portion is formed in the gap portion forming direction from the first layer portion. The two-layer foam molding apparatus according to any one of claims 4 to 7, wherein the two-layer foam molding apparatus is configured to protrude to the side and to protrude more than the gap portion.   The damming portion forming concave portion and the projecting shape portion have a seal surface that is substantially perpendicular to the gap portion forming direction on the outer surface portion, and a taper surface for anti-corrosion tapering to the inner surface portion. The two-layer foam molding apparatus according to claim 8. In the two-layer foam molded product in which the first layer portion and the foamable second layer portion are integrated,
The two-layer foam-molded product, wherein the second layer portion integrally has a wraparound portion that wraps around an edge of the shared contact portion of the first layer portion.

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