JP5747665B2 - Injection mold - Google Patents

Description

  The present invention relates to an injection mold. More specifically, the present invention relates to an injection mold for a sandwich molded product comprising a surface layer and an inner layer, the inner layer being included in the surface layer, and an injection mold for a hollow molded product having a hollow portion formed therein.

  As one of the multilayer molded products in the resin molded product, a sandwich molded product is known which includes a surface layer and an inner layer, and the inner layer is included in the surface layer. The main purpose of this sandwich molded product is to design both front and back surfaces or to use recycled resin for the inner layer. Also, a hollow molded product having a hollow portion formed therein is mainly known for the purpose of reducing the weight.

  Unlike the multilayer molded product in which another layer is laminated only on one surface of one layer, the former sandwich molded product is a multilayer molded product in which an inner layer is included in a surface layer. The injection molding method for molding such a sandwich molded product is also called a co-injection method, and is roughly classified into two. An appropriate amount of the molten resin for the surface layer is injected and filled, and then the molten resin for the inner layer is injected and filled into the molten resin for the surface layer, and one of them is a multi-stage molding method that fills the mold cavity with these two molten resins. is there.

  The latter hollow molded product is literally a resin molded product in which a hollow portion is formed. The injection molding method for molding such a hollow molded product is a blow molding method or after molding a single hollow molded product in a semi-hollow body state, and then dividing each semi-hollow body into a respective split surface. Are moved so as to face each other and then molded by various methods such as bonding in a mold. A hollow injection molding method (gas-assisted injection) in which a pressurized gas is injected into a molten resin injected and filled into a mold to form a hollow portion in the molten resin and then the injected pressurized gas is discharged. One of them is also called a forming method.

  Patent Document 1 is a composite molding method (multilayer molding method) and an injection molding machine classified as a multi-stage molding method for molding the former sandwich molded product, and includes a fixed mold (fixed mold) and a movable mold (movable mold). After injecting the first material (surface layer molten resin) through the first injection cylinder (injection unit) into the cavity (mold cavity) formed by the above, the first material and the first material through the second injection cylinder Discloses a composite molding method characterized by injecting a different second material (inner layer molten resin) into the first material and filling the first material along the shape of the cavity with the second material. Has been.

  Patent Document 2 relates to a hollow injection molding method for molding the latter hollow molded article, and a molten synthetic resin material injected into a horizontally long cavity space (mold cavity) formed in a mold. In a gas injection nozzle device used when injecting a pressurized gas into (molten resin), the opening direction of the jet port from which the gas is injected is matched with the longitudinal direction of the horizontally long cavity space There is disclosed a gas injection nozzle device used in an injection molding method (injection molding method) characterized by the above.

  Here, as described in the specification of Patent Document 1 (the same paragraph 0020), the surface layer of the sandwich molded product may be referred to as a skin layer, and the inner layer may be referred to as a core layer. First, the molten resin injected and filled in the mold cavity is cooled by contact with other substances such as the inner surface of the mold cavity, the gas in the mold cavity, or resin or insert material. A thin film-like cooling solidified layer formed at the contact portion is referred to as a skin layer.

  In addition, the parentheses in the descriptions relating to Patent Document 1 and Patent Document 2 described the constituent requirements of the present invention that are considered to be equivalent to or similar to the constituent requirements immediately before the parentheses, so that the understanding of the present invention is easy. Therefore, it does not suggest that the constituent requirements immediately before the parenthesis and the constituent requirements in the parenthesis match.

Japanese Patent Laid-Open No. 08-174603 JP 2008-213344 A

  In the composite molding method described in Patent Document 1, which is classified as a multistage molding method for molding a sandwich molded product, a resin material having high strength such as an engineering plastic resin is used, or the appearance of a product, etc. When the skin layer formed on the surface of the first material is strong, such as when it is necessary to form a thick skin layer of the first material as the surface layer due to requirements in the product specifications, a short shot is first made in the cavity. The skin layer of the first material formed at the contact portion between the first material to be injected and filled and the tip portion of the valve gate pin protruding into the cavity also becomes strong. As a result, even if a concave portion is formed on the surface of the first material by the valve gate pin, and the second material as the inner layer is injected and filled into the concave portion from the valve gate, the second material is caused by the flow pressure of the second material. There is a possibility that the strong skin layer formed in the concave portion cannot be completely penetrated and the first material is not surely filled. In that case, since the short shot with respect to the full shot is injected and filled, the second resin serving as an inner layer is formed between the first material having a low resin internal pressure and the mold cavity, or in the unfilled portion of the mold cavity. There is a problem that a so-called resin reversal failure occurs.

  Also in the gas injection nozzle device according to the hollow injection molding method for molding a hollow molded article described in Patent Document 2, the skin layer formed on the surface of the molten synthetic resin material at the time of injection filling of the hollow molded article is patented. In the case of being strong due to the reason described in Document 1, the melt formed at the contact portion between the molten synthetic resin material injected and filled into the mold cavity and the tip of the gas injection nozzle protruding into the mold cavity. The skin layer of the synthetic resin material is also strong. Further, the tip of the gas injection nozzle device of Patent Document 2 has injection gas filling because there is no gas blocking / opening mechanism for controlling the injection of pressurized gas and preventing the backflow of molten resin from the nozzle tip. The opening area of the nozzle tip is small compared to the case where there is such a gas blocking / opening mechanism so that the molten synthetic resin material does not flow backward from the nozzle tip.

  As a result, in order to form a hollow portion, the pressurized gas injected from the injection port at the tip of the gas injection nozzle completely penetrates the strong skin layer formed in the recess by the flow pressure of the pressurized gas. Cannot be injected into the melted synthetic resin material. In that case, similarly to Patent Document 1, pressurized gas for forming the hollow portion is blown out between the molten synthetic resin material and the mold cavity or in the unfilled portion of the mold cavity to form the hollow portion. Insufficient gas capacity to make it happen. This injection of pressurized gas not only causes unintended product appearance defects such as ejection marks, but also the capacity of the pressurized gas is insufficient, so filling the mold cavity with the molten synthetic resin material containing the pressurized gas Defects, pressurization gas pressure in the hollow part decreases, the pressing force of the molten synthetic resin material against the inner surface of the mold cavity due to the pressurized gas pressure decreases, and the transferability to the skin layer of the inner surface shape of the mold cavity That is, the product appearance of the hollow molded product is deteriorated. Above all, there is a problem that a desired hollow portion is not formed.

  Here, the short shot in Patent Document 1 means an injection filling state in which the injection filling amount (volume) in the injection filling into the mold cavity is insufficient to satisfy the volume of the mold cavity. Thus, the full shot means an injection filling state that satisfies the volume of the mold cavity. In general, full shot is applied to the molten resin in the mold cavity almost uniformly in the full shot compared to the short shot, and the internal pressure of the molten resin in the mold cavity is substantially uniform. By being raised, it is said that the product appearance of the resin molded product is excellent. In Patent Document 2, there is no description as to whether the molten synthetic resin material into the mold cavity is injected and filled in a short shot or a full shot during injection filling of a hollow molded product, but the description in the same specification From the same drawing, it is presumed that injection filling is performed in the same short shot as in Patent Document 1. (If full injection is used, the mold cavity is filled with molten synthetic resin material, so pressurized gas can be injected at a high pressure in accordance with the injection resistance at the time of gas injection. In order to reduce the volume, it is necessary to expand the volume of the mold cavity in synchronism with the injection of the pressurized gas, but there is no content that suggests them in the specification or drawings.

  The present invention has been made in view of the above-described problems. Specifically, a skin layer (cooled solidified layer) formed on the surface of a molten resin previously injected and filled into a mold cavity is provided. Even in a strong case, an injection mold capable of reliably filling and injecting another fluid into the molten resin, more specifically, a sandwich capable of reliably filling the molten resin for the inner layer into the molten resin for the surface layer It is an object to provide a mold for injection molding of a molded product and a mold for injection molding of a hollow molded product capable of forming a desired hollow portion by reliably injecting a pressurized gas into a molten resin. .

According to the first aspect of the present invention, as shown in claim 1, a first fluid flow channel for flowing a first fluid into a mold cavity;
A second fluid flow path for allowing a second fluid to flow into the mold cavity;
The second fluid flow path is movably disposed in an opening portion communicating with the mold cavity,
In the advanced state, the opening portion of the second fluid flow path is sealed, and the tip is protruded into the mold cavity by a predetermined amount.
In the retracted state, the opening portion of the second fluid flow path is opened, and the tip portion is retracted out of the mold cavity.
A seal pin mechanism having a shape in which the shape of the tip portion gradually decreases the cross-sectional area perpendicular to the advance / retreat direction in the advance direction;
Equipped with a,
The concave portion formed in the first fluid by the seal pin mechanism is formed in a contact portion with the tip portion of the seal pin mechanism so as to have a pointed shape toward the inside of the mold cavity, and the flow of the second fluid It was allowed to converge in the shape moiety Tsu該尖is achieved by the first injection mold Ru is filled with the second fluid in the fluid.

  When the first fluid is caused to flow into the mold cavity, that is, as will be described later, when the first fluid is a molten resin and this molten resin is injected and filled into the mold cavity, the mold of the second fluid flow path is used. The seal pin mechanism disposed in the opening portion communicating with the mold cavity so as to freely advance and retract is kept in a forward state, thereby preventing the first fluid (molten resin) from flowing into the second fluid flow path and the mold. A recess is formed on the surface of the first fluid (molten resin) by the tip of the seal pin mechanism that protrudes by a predetermined amount into the cavity. Similar to the surface of the first fluid (molten resin), a skin layer is also formed in this recess. It is formed. However, the shape of the tip portion is a shape that gradually decreases the cross-sectional area perpendicular to the advance / retreat direction in the advance direction, that is, a shape that becomes sharper toward the inside of the mold cavity. With respect to the inner surface, the volume and the heat capacity of the tip end portion become smaller toward the inside of the mold cavity, and the cooling and solidifying action for cooling and solidifying the molten resin at the contact portion is also reduced. In addition, the shape of the concave portion is formed so as to be sharper toward the inside of the mold cavity, and the temperature of the first fluid (molten resin) becomes higher as it goes to the inside of the mold cavity, so that it is difficult to be cooled and solidified. . For these reasons, the thickness of the skin layer formed in the concave portion is reduced as it goes to the tip (inside the mold cavity), and the strength gradually decreases.

  As a result, the seal pin mechanism is set in the retracted state, the opening portion communicating with the mold cavity of the second fluid flow path is opened, and the second portion is formed in the recess formed on the surface of the first fluid (molten resin). When the fluid is filled and injected at a predetermined pressure, the shape that sharpens toward the inside of the mold cavity also adds a pressure increase effect due to the flow convergence effect that converges the flow of the second fluid, and the strength of the skin layer is increased. The second fluid is filled and injected into the molten resin through the lowered portion. Thus, even when a strong skin layer is formed on the surface of the first fluid (molten resin), the second fluid can be reliably filled and injected into the first fluid (molten resin).

Specifically, as shown in claim 2, the injection mold includes a molten resin for a surface layer and a molten resin for an inner layer in which the first fluid and the second fluid form a surface layer, respectively. Because
In the molten resin for the surface layer, the seal pin mechanism is moved forward, and injected and filled from the first fluid flow path into the mold cavity.
The seal pin mechanism is set in a retracted state, and the flow of the molten resin for the inner layer injected and filled from the second fluid flow path into the mold cavity is transferred to the surface of the molten resin for the surface layer and the tip portion of the seal pin mechanism. The concavity formed by the method is converged and filled in the sharp shape portion formed in the contact portion with the tip portion of the seal pin mechanism ,
The injection mold according to claim 1, wherein a sandwich molded product is formed which includes the surface layer and the inner layer, and the inner layer is included in the surface layer.

  Thus, when the injection mold according to claim 1 is configured as a sandwich mold for molding a sandwich molded product, a strong skin layer is formed on the surface of the molten resin for the surface layer as the first fluid. Even when is formed, the inner layer molten resin as the second fluid can be reliably filled into the surface layer molten resin.

In the injection mold, as shown in claim 3, the first fluid and the second fluid are a molten resin and a pressurized gas, respectively.
In the resin molded body formed by causing the seal pin mechanism to move forward and injection filling from the first fluid flow path into the mold cavity,
Wherein by the seal pin mechanism in a retracted state, the flow of the pressurized gas is injected from the second fluid flow path into the mold cavity was formed by the distal end portion of the seal pin mechanism to the molten resin surface A hollow molded article having a hollow portion formed therein is formed by converging and injecting into the sharp shape portion formed at the contact portion of the concave portion with the tip portion of the seal pin mechanism. You may comprise as a metal mold | die for injection molding of Claim 1.

  Thus, if the injection mold according to claim 1 is configured as a hollow molding mold for molding a hollow molded product, a strong skin layer is formed on the surface of the molten resin as the first fluid. Even in such a case, it is possible to reliably inject the pressurized gas, which is the second fluid, into the molten resin to form a desired hollow portion.

  Further, as shown in claim 4, the injection mold has a mold opening / closing operation by a mold opening / closing mechanism of an injection molding machine to which the injection mold is attached, and the volume of the mold cavity, and The injection mold according to any one of claims 1 to 3, wherein the mold is expanded / reduced by at least one of moving operations of a movable part arranged in the injection mold. It is also good.

  Thus, if the volume of the mold cavity can be expanded / reduced, when the injection mold is used as a sandwich mold or a hollow mold, the first fluid is performed first. Reduced mold by reducing the volume of the mold cavity from the product volume so that the injection filling rate is approximately 100%, that is, full shot, at the time of injection filling of (surface layer molten resin or molten resin) The cavity is filled with the first fluid, the clamping force is applied to the first fluid in the mold cavity substantially uniformly, and the pressure of the first fluid is increased substantially uniformly, so that substantially the entire surface of the first fluid is applied. A skin layer (cooled solidified layer) that is cooled and solidified by contact with the inner surface of the mold cavity is formed, and the outflow and ejection of the second fluid that is filled and injected into the first fluid later to the outside of the first fluid is suppressed. Is done. In addition, since high transferability of the inner surface of the mold cavity to the skin layer is ensured, the first fluid is injected and filled in a short shot, and then the second fluid is filled and injected in the mold cavity. The shape of the inner surface of the mold cavity is transferred to the skin layer (cooled solidified layer) formed on the surface of the first fluid only by the flow pressure of the first fluid that freely flows through the first fluid. Product appearance is improved with respect to general sandwich molded products and hollow molded products.

  Also, the injection filling resistance and injection resistance are reduced by expanding the volume of the mold cavity in conjunction with injection filling of molten resin for inner layer in sandwich molding and injection of pressurized gas in hollow molding. Further, the filling ratio of the inner layer molten resin to the product volume and the hollow ratio of the hollow portion can be improved. Further, by using a molten resin containing a foaming agent and expanding the volume of the mold cavity to perform expanded foam molding, a sandwich molded product or a hollow molded product having a foamed layer can be molded. Furthermore, after expanding the volume of the mold cavity beyond the product volume, injection injection of molten resin for inner layer in sandwich molding and injection of pressurized gas in hollow molding, injection is reduced by reducing to the product volume. The same effect as the compression molding method or injection press molding method can be expected.

An injection mold according to the present invention includes a first fluid flow path for allowing a first fluid to flow into a mold cavity,
A second fluid flow path for allowing a second fluid to flow into the mold cavity;
The second fluid flow path is movably disposed in an opening portion communicating with the mold cavity,
In the advanced state, the opening portion of the second fluid flow path is sealed, and the tip is protruded into the mold cavity by a predetermined amount.
In the retracted state, the opening portion of the second fluid flow path is opened, and the tip portion is retracted out of the mold cavity.
A seal pin mechanism having a shape in which the shape of the tip portion gradually decreases the cross-sectional area perpendicular to the advance / retreat direction in the advance direction;
Equipped with a,
The concave portion formed in the first fluid by the seal pin mechanism is formed in a contact portion with the tip portion of the seal pin mechanism so as to have a pointed shape toward the inside of the mold cavity, and the flow of the second fluid It was allowed to converge in the shape moiety Tsu該尖, since the injection mold Ru is filled with the second fluid to the first fluid, first into the mold cavity on the surface of the injection filling molten resin Even when the formed skin layer (cooled solidified layer) is strong, other fluid can be reliably filled and injected into the molten resin. More specifically, in the sandwich molded product, the molten resin for the inner layer can be reliably filled in the molten resin for the surface layer, and in the hollow molded product, the desired hollow portion can be obtained by reliably injecting the pressurized gas into the molten resin. Can be formed.

It is a schematic sectional drawing of the metal mold | die for injection molding which concerns on Example 1 of this invention. It is a schematic sectional drawing which shows the first half of the shaping | molding process of the injection molding method of the sandwich molded product which uses the metal mold | die for injection molding which concerns on Example 1 of this invention. It is a schematic sectional drawing which shows the latter half of the shaping | molding process of the injection molding method of the sandwich molded product which uses the metal mold | die for injection molding which concerns on Example 1 of this invention. It is an enlarged view of the seal pin mechanism front-end | tip part of the injection mold which concerns on Example 1 of this invention. It is a schematic sectional drawing of the metal mold | die for injection molding which concerns on Example 2 of this invention. It is an enlarged view of the seal pin mechanism front-end | tip part of the injection mold which concerns on Example 2 of this invention. It is a schematic sectional drawing which shows another form of the seal pin mechanism front-end | tip part of the injection mold which concerns on Example 1 of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings.

  A first embodiment of the present invention will be described with reference to FIGS. 1 to 4 and FIG. 1 is a schematic cross-sectional view of an injection mold according to a first embodiment of the present invention. 2 (a) to 2 (c) are schematic sectional views of the mold showing the first half of the molding process of the injection molding method for sandwich molded products according to Example 1 of the present invention. FIG. 3A to FIG. 3C are schematic cross-sectional views of the mold showing the latter half of the molding process of the sandwich molded product injection molding method according to Example 1 of the present invention. FIG. 4 is an enlarged view of the front end portion of the seal pin mechanism of the injection mold according to the first embodiment of the present invention. 4 (a) is an enlarged view of the main part A in FIG. 2 (c), FIG. 4 (b) is a skin layer formed at the tip of the seal pin mechanism in the main part C of FIG. 4 (a), and FIG. ) Shows an enlarged view of the main part B in FIG. 3A and a skin layer formed at the tip of the seal pin mechanism in the main part C of FIG. 4A. FIG. 7 is a schematic cross-sectional view showing another embodiment of the tip portion of the seal pin mechanism of the injection mold according to the first embodiment of the present invention.

  In Example 1, the injection mold of the present invention is constituted as a sandwich mold for molding a sandwich molded product comprising a surface layer and an inner layer, and the inner layer is included in the surface layer. In explaining the sandwich molding die, a general-purpose injection molding machine should be explained on the side of the injection molding machine to which the sandwich molding die is attached. It is only a point that two or more sets are required for the surface layer and the inner layer, and there are no other special configuration requirements. Therefore, the description of the injection molding machine is omitted, and only related constituent requirements are described. FIGS. 1 to 4 and 7 are schematic cross-sectional views of only the constituent elements necessary for explaining the molding process such as a mold, and these schematic cross-sectional views are longitudinal sections along the longitudinal direction of the injection molding machine. Either a side view (side sectional view) or a transverse sectional view (planar sectional view) may be used.

  First, an injection molding die configured as a sandwich molding die according to Embodiment 1 of the present invention will be described with reference to FIG. As shown in FIG. 1, a first injection unit 17 for injecting a surface layer molten resin 9b (first fluid) to a fixed mold 2 attached to a fixed plate (not shown) has a tip from the back of the fixed plate. The nozzle is arranged to be able to contact and separate. A surface layer resin flow path 9c (first fluid flow path) for filling the mold cavity 9a with the surface layer molten resin 9b injected from the first injection unit 17 is disposed in the fixed mold 2, and the surface layer resin flow At the end of the passage 9c on the mold cavity 9a side, a gate valve (resin cutoff opening switching valve) 9d is provided at a gate portion communicating with the mold cavity 9a. In addition to the first injection unit 17, a second injection unit 18 for injecting the inner layer molten resin 10 b, which is the second fluid, is disposed in the fixed mold 2 so that the tip nozzle can be contacted and separated. .

  Similarly to the first injection unit 17, the inner layer resin flow path 10c (second fluid flow path) for filling the mold cavity 9a with the inner layer molten resin 10b (second fluid) injected from the second injection unit 18. Is disposed in the fixed mold 2, and a seal pin mechanism 10 d is disposed so as to be capable of moving forward and backward at the opening portion at the end of the inner layer resin flow path 10 c on the mold cavity 9 a side. As shown in FIG. 1, in the forward state, the seal pin mechanism 10d seals the opening at the end of the inner layer resin flow path 10c on the mold cavity 9a side, and places its tip in the mold cavity 9a. A fixed amount is projected. Further, the seal pin mechanism 10d is formed such that the tip portion has a shape that gradually decreases the cross-sectional area perpendicular to the advance / retreat direction in the advance direction, that is, a shape that becomes sharper toward the inside of the mold cavity 9a. ing.

  Regarding the amount of protrusion of the tip of the seal pin mechanism 10d to the mold cavity 9a, the angle of sharpening, etc., the resin material of the surface layer molten resin 9b, the thickness and strength of the formed skin layer, the tip of the seal pin mechanism 10d A suitable specification may be selected as appropriate depending on the product thickness of the portion protruding from the mold cavity 9a. However, at least the amount of protrusion of the tip portion of the seal pin mechanism 10d into the mold cavity 9a is approximately half the product thickness of the portion where the tip portion protrudes into the mold cavity 9a (approximately the center of the die cavity 9a at the portion). It is preferable to project to the position.

  In addition, in order to simplify the explanation and illustration of the molding process of the sandwich molded product using the injection mold according to Example 1 of the present invention to be described later, the mold cavity 9a side end of the inner layer resin flow path 10c As shown in FIG. 1 (FIG. 7 (a)), the seal pin mechanism 10d disposed in the opening portion of the portion has a straight body portion continuous with the distal end portion in the advanced state, so that the inner layer resin flow path 10c is Although the opening portion at the end portion on the mold cavity 9a side is sealed, as shown in FIG. 7 (b), the shape of the opening portion at the end portion on the mold cavity 9a side of the inner layer resin flow path 10c is A taper surface having substantially the same shape as the taper surface of the front end portion of the seal pin mechanism 10d may be used, and in the advanced state, the taper surface of the front end portion may be pressed against the taper surface of the opening portion for sealing. In this case, high sealing performance of the opening portion of the inner layer resin flow path 10c can be ensured, and the amount of protrusion of the tip portion of the seal pin mechanism 10d into the mold cavity 9a can be precisely controlled. Furthermore, as shown in FIG. 7 (c), the shape of the front end portion of the seal pin mechanism 10d and the opening portion of the inner layer resin flow path 10c is shown in FIG. 7 (a) as shown in FIG. If a stepped taper surface combined with the shape of the taper surface is formed, the end of the taper surface of the opening portion of the inner layer resin flow path 10c shown in FIG. 7B is made thicker and has higher rigidity. It is possible to maintain the high sealing performance of the opening portion of the inner layer resin flow path 10c for a long period of time. As described above, the seal pin mechanism 10d seals the opening portion of the end portion of the inner layer resin flow path 10c on the mold cavity 9a side, and projects the tip portion into the mold cavity 9a by a predetermined amount. If possible, various forms can be selected.

  Returning to FIG. The tip of the seal pin mechanism 10d is formed in a shape that gradually decreases the cross-sectional area perpendicular to the advance / retreat direction in the advance direction, that is, a shape that becomes sharper toward the inside of the mold cavity 9a, A piston is formed at the other end of the distal end portion, and a hydraulic cylinder is configured which is combined with a space portion in the fixed mold 2 and uses a straight body portion continuous from the distal end portion of the seal pin mechanism 10d as a piston rod. . When the hydraulic pressure is applied to the head side of the hydraulic cylinder, the seal pin mechanism 10d is moved forward as shown in FIG. 1, and when the hydraulic pressure is operated to the rod side, the inner layer resin flow path 10c (second fluid flow path). The opening portion of the end portion on the mold cavity 9a side is opened, and the tip portion is retracted out of the mold cavity 9a. The mechanism for advancing and retracting the seal pin mechanism 10d may be a hydraulic cylinder as shown in FIG. 1, or an air cylinder, various actuators combining a motor and a ball screw, or the like.

  A movable mold 4 that is combined with the fixed mold 2 to form a mold cavity 9a is attached to a movable plate (not shown) so as to face the fixed mold 2, and a mold opening / closing mechanism (not shown) is used for the injection molding machine. It is arranged to be movable in the longitudinal direction (hereinafter referred to as the mold opening / closing direction). In the first embodiment, each of the fixed mold 2 and the movable mold 4 has a shearing edge structure in which the split surfaces of the respective molds (also referred to as mold split surfaces, parting surfaces, and split surfaces) may be used. It is assumed that the volume of the mold cavity is variable by the mold opening / closing operation by the mold opening / closing mechanism of the injection molding machine.

  Here, as for the first injection unit 17 and the second injection unit 18, as shown in FIG. 1, a first fluid channel and a gate valve 9d communicating with each of the injection units, and a second fluid channel and a seal pin mechanism. 10d is arranged in either the fixed mold 2 or the movable mold 4, the arrangement of the two injection units or either injection unit can be connected to either the fixed mold 2 or the movable mold 4 There is no restriction on the mold side in particular. Further, when the surface layer molten resin 9b (first fluid) and the inner layer molten resin 10b (second fluid) are made of the same resin material, even if the injection molding machine has only one set of injection units, the surface layer 1 and the seal pin mechanism 10d as shown in FIG. 1 are arranged in the resin flow paths branched from the resin flow paths for the molten resin for the inner layer and the molten resin for the inner layer, respectively. For example, the present invention can be implemented.

  In addition, the above-mentioned mold shear edge structure is sometimes called a squeezing structure or an inlay structure, and is generally known as a structure of a fitting portion that forms a split surface of the mold. In addition, the mold cavity was injection-filled into the mold cavity by forming between the fixed mold and the movable mold a fitting portion that extends in the mold opening and closing direction and can be inserted and removed while sliding on each other. This is a structure capable of preventing the molten resin from leaking out of the mold even when the mold is opened for a predetermined amount. A mold having such a shear edge structure is an expanded foam molding method (sometimes referred to as a core back foam molding method) in which the mold is opened in a minute mold state during the molding process, a compression molding method, In-mold coating forming method (sometimes called in-mold coating method or in-mold coating method).

  Next, a molding process of a sandwich molded product using the injection mold according to the first embodiment of the present invention will be described with reference to FIGS. FIG. 2A shows the mold opening state before the start of the molding cycle. Each component is as described in FIG. In order to simplify the explanation and drawings, the surface layer resin flow path 9c (first fluid flow path) for flowing the surface layer molten resin 9b (first fluid) and the inner layer flowed for the inner layer molten resin 10b (second fluid). The resin flow path 10c (second fluid flow path) is in a state where nothing flows in, but actually, after completion of the injection filling of the surface layer molten resin 9b and the inner layer molten resin 10b in the previous cycle. For the next cycle to be described, each resin flow path is already filled with each weighed molten resin.

  Then, as shown in FIG. 2B, the movable mold 4 is moved to the fixed mold 2 side by a mold opening / closing mechanism (not shown), and the movable mold 4 and the fixed mold 2 are closed. Thereafter, with the mold clamping force applied, the gate valve 9d of the surface layer resin flow path 9c (first fluid flow path) is opened (not shown because of the open state), and the surface layer for forming the surface layer 9 later. Mold cavity formed by the movable mold 4 and the fixed mold 2 from the first injection unit 17 through the surface layer resin flow path 9c (first fluid flow path) from the molten resin 9b (first fluid). A resin injection filling process for the surface layer for injection filling in 9a is performed. In this resin injection filling process for the surface layer, the seal pin mechanism 10d provided at the opening portion of the inner layer resin flow path 10c (second fluid flow path) on the mold cavity 9a side end has a predetermined amount of the In the state of protruding into the mold cavity 9a, the opening portion at the end of the inner layer resin flow path 10c on the mold cavity 9a side is sealed, and the surface layer molten resin 9b injected and filled into the mold cavity 9a is provided. There is no backflow to the inner layer resin flow path 10c.

  In this surface layer resin injection filling step, the mold cavity 9a has its mold so that the injection filling rate is substantially 100% with respect to the injection filling amount (volume) of the surface layer molten resin 9b (first fluid). This is a state in which the volume of the cavity is smaller than the product volume. By reducing the volume of the mold cavity 9a from the product volume so that the injection filling rate becomes approximately 100% (full shot), the reduced mold cavity 9a is filled with the molten resin 9b for the surface layer, A mold clamping force is applied substantially uniformly to the surface layer molten resin 9b in the mold cavity 9a, and the resin pressure of the surface layer molten resin 9b is increased substantially uniformly, so that a mold cavity is formed on substantially the entire surface layer molten resin 9b. A skin layer (cooled solidified layer) that is cooled and solidified by contact with the inner surface of 9a is formed, and the molten resin 9b for the surface layer of the molten resin 10b for the inner layer (second fluid) that is injected and filled into the molten resin 9b for the surface layer later. To the outside, so-called resin reversal failure is suppressed. Further, since a high transferability of the inner surface of the mold cavity 9a to the skin layer is ensured, a general sandwich molded product, that is, a molten resin 9b for the surface layer is injected and filled in a short shot, and then the inner layer is performed. The inner surface shape of the mold cavity 9a is melted by the injection of the molten resin 10b for the surface layer only by the flow pressure applied nonuniformly by the free flow of the molten resin 9b for free flow in the mold cavity 9a. The appearance of the product is improved with respect to the sandwich molded product transferred to the skin layer (cooled solidified layer) formed on the surface of the resin 9b.

  The surface layer molten resin 9b (first fluid) is cooled in the mold immediately after being injected and filled into the mold cavity 9a, and cooling solidification shrinkage proceeds. Therefore, from the volume of the reduced mold cavity 9a, In order to ensure the formation of the skin layer (cooled solidified layer) of the molten resin 9b for the surface layer and the high transferability to the skin layer, it is more preferable to inject and fill at least the amount of cooling solidified shrinkage (volume). preferable. Here, the skin layer formed by contact with the inner surface of the mold cavity 9a is in contact with the gas in the mold cavity 9a, that is, the surface of the surface layer molten resin 9b not in contact with the inner surface of the mold cavity 9a. Although it is strong against the skin layer formed in the layer, it is not a completely cured layer, and its temperature is higher than the resin softening point temperature or the glass solidification temperature, and cooling solidification is still in progress. It is a thin film-like layer that exhibits rubber-like elastic behavior, and can be expanded and contracted in a variable manner in the volume of the mold cavity 9a.

  On the other hand, in the case of a mold configuration in which the volume of the mold cavity 9a cannot be reduced (expanded) from the product volume, the surface layer resin injection filling process is generally performed by a short shot. In that case, a resin flow is formed in the mold cavity 9a so as not to deteriorate the transferability of the surface layer molten resin 9b (first fluid) to the skin layer while preventing the resin reversal failure. In order to achieve this, the injection filling amount (volume) of the surface layer molten resin 9b to be injected and filled first, the injection filling pressure, the resin temperature, etc., and then the inner layer molten resin 10b to be injected and filled into the surface layer molten resin 9b Needless to say, it is necessary to sufficiently examine and adjust the injection filling timing, injection filling amount (volume), injection filling pressure, resin temperature, and the like of the (second fluid).

  FIG. 2C shows a state in which the surface layer resin injection filling step is completed and the gate valve 9d of the surface layer resin flow path 9c (first fluid flow path) is closed. At this time, the seal pin mechanism 10d is in an advanced state in which the opening portion of the inner layer molten resin flow path 10c (second fluid flow path) is sealed. Here, FIG. 4A is an enlarged view of the distal end portion of the seal pin mechanism 10d shown by the main part A of FIG. 2C. As shown in FIG. 4A, the surface layer molten resin 9b (first fluid) in the mold cavity 9a is in a molten state with the skin layer 9e formed at the contact portion with the inner surface of the mold cavity 9a. It is the state of the surface layer 9 (resin molding) comprised by the molten layer 9f. As a matter of course, the skin layer is also applied to the main portion C of FIG. 9e is formed. As shown in FIG. 4B, the skin layer 9e formed in the contact portion is closer to the tip of the tip portion of the seal pin mechanism 10d, and is closer to the inside of the mold cavity 9a. The thickness is formed thin, and the strength gradually decreases.

  This is because the shape of the tip of the seal pin mechanism 10d is a shape that gradually decreases the cross-sectional area perpendicular to the advance / retreat direction in the advance direction, that is, a shape that becomes sharper toward the inside of the mold cavity 9a. The volume and the heat capacity of the tip portion of the inner surface of the mold cavity 9a become smaller toward the inside of the mold cavity 9a, and the cooling and solidifying action for cooling and solidifying the molten resin at the contact portion is also reduced. The shape of the recess formed on the surface of the surface layer molten resin 9b (first fluid) according to the shape of the tip of the seal pin mechanism 10d is also formed in a sharp shape toward the inside of the mold cavity 9a. The reason that the temperature of the molten resin 9b for the surface layer is closer to the center of the molten layer 9f as it goes to the inside of the mold cavity 9a, and is thus hard to be cooled and solidified. It is due. Further, finally, in order to keep the sandwich molded product in the mold cavity 9a at the control temperature of the mold cavity 9a that needs to be cooled and solidified, the resin inside the mold cavity 9a is melted and kept in a fluid state at all times. Furthermore, the management temperature of the inner layer resin flow path 10c (second fluid flow path), which is also a hot runner equipped with heating means and heat insulation / heat retention means, is high, and the seal pin mechanism 10d disposed in the inner layer resin flow path 10c The temperature is also kept high. Therefore, the cooling and solidifying action of the seal pin mechanism 10d is low with respect to the inner surface of the mold cavity 9a even if the effect of reducing the heat capacity due to the volume reduction of the tip portion is excluded. The portion that contacts the tip of the seal pin mechanism 10d is less likely to be cooled and solidified than the portion that contacts the inner surface, and the formed skin layer 9e is thin and weak.

  Next, as shown in FIG. 3 (a), a mold cavity expanding step for expanding the volume of the mold cavity 9a to the product volume is performed during or after the surface layer resin injection filling step. A gate opening / closing mechanism (not shown) is used until the gate valve 9d of the resin flow path 9c for the surface layer (first fluid flow path) is closed and the movable mold 4 becomes the minute mold opening L1 in the direction away from the fixed mold 2. The mold is opened to expand the volume of the mold cavity 9a. The volume of the mold cavity 9a in a state where the mold is opened until the micro mold opening amount L1 is substantially the same as the product volume. Simultaneously with this mold cavity expansion step or after a predetermined time has elapsed, the seal pin mechanism 10d of the inner layer resin flow path 10c (second fluid flow path) is set in the retracted state, and the inner layer melting that forms the inner layer 10 later is performed. The resin 10b (second fluid) is formed on the contact surface between the surface layer molten resin 9b (first fluid) and the inner surface of the mold cavity 9a via the inner layer resin flow path 10c from the second injection unit 18. An inner layer resin injection filling process is performed in which the skin layer (cooled solidified layer) 9e of the surface layer molten resin 9b is passed through and injected into the surface layer molten resin 9b.

  Here, an enlarged view of the front end portion of the seal pin mechanism 10d shown by the main portion B in FIG. 3A and a skin layer formed at the front end portion of the seal pin mechanism 10d in the main portion C in FIG. 4A are shown. This is shown in FIG. As shown in FIG. 4 (b), the tip of the seal pin mechanism 10d having a pointed shape toward the inside of the mold cavity 9a is made to recede as shown in FIG. 4 (c), and is moved out of the mold cavity 9a. When retracted, the opening portion of the inner layer resin flow path 10c (second fluid flow path) is opened, and the inner layer molten resin 10b (first flow) is formed in the recess formed on the surface of the surface layer molten resin 9b (first fluid). 2 fluid) is injection-filled by a predetermined amount at a predetermined pressure. The resin flow of the injection-filled inner layer molten resin 10b is converged by the shape of the concave portion that becomes sharper toward the inside of the mold cavity 9a, and the flow pressure is gradually increased. The tip of the resin flow of the inner layer molten resin 10b whose flow pressure is increased by the flow convergence effect collides with the bottom of the concave portion having the thinnest skin layer 9e and the low strength described above. Thus, the resin flow can be surely injected and filled in the molten layer 9f in the surface layer molten resin 9b through the skin layer 9e of the surface layer molten resin 9b.

  In addition, the resin internal pressure of the inner layer molten resin 10b (second fluid) in the inner layer resin flow path 10c (second fluid flow path) is set in advance to the surface layer molten resin 9b (first fluid) in the mold cavity 9a. If the tip of the seal pin mechanism 10d is set in a retracted state and is injected and filled with the inner layer molten resin 10b after the pressure in the inner layer is sufficiently increased, the surface layer molten resin 9b is formed in the opening portion of the inner layer resin flow path 10c. When the tip end portion of the seal pin mechanism 10d is moved forward and the injection filling of the inner layer molten resin 10b is completed, the inner resin layer of the inner layer molten resin 10b in the inner layer resin flow path 10c is also filled. If the tip of the seal pin mechanism 10d is advanced while the pressure is sufficiently higher than the resin internal pressure of the surface layer molten resin 9b in the mold cavity 9a, the surface layer melts in the opening of the inner layer resin flow path 10c. Resin 9b Not flow back can be completed injection filling of the inner layer for the molten resin 10b.

  Here, the mold cavity expanding step and the inner layer resin injection filling step are interlocked so that the mold opening amount of the movable mold 4, that is, the volume expansion amount of the mold cavity 9 a is the surface layer molten resin 9 b (first fluid). ) The mold opening speed and the mold position by the mold opening / closing mechanism are the same as the injection filling quantity (volume) of the inner layer molten resin 10b (second fluid) to be injected and filled, or the predetermined quantity (volume) is decreased. It is possible to control the holding force and the like so that the movable mold 4 is opened until the volume of the mold cavity 9a reaches the product volume, that is, the minute mold opening amount L1 so that the above-described gap does not occur. The surface layer resin is maintained by keeping the skin layer 9e of the molten resin 9b for the surface layer formed on the contact surface between the tip portion of the seal pin mechanism 10d of the resin flow path 10c and the inner surface of the mold cavity 9a. Channel 10 It is very important to prevent the occurrence of resin inversion failure in (second fluid passage) portion.

  Further, the interlocking of the mold cavity expanding step and the inner layer resin injection filling step is performed by forming the skin layer 9e (cooled solidified layer) of the surface layer molten resin 9b (first fluid) and the skin layer. It is also preferable to prevent the occurrence of resin reversal failure from the skin layer 9e of the molten resin 9b for the surface layer by reducing the injection filling resistance of the molten resin 10b (second fluid) for the inner layer while ensuring high transferability to the surface. . Further, as described above, the interlock control between the mold cavity expansion process and the inner layer resin injection filling process is based on the increase in the injection filling amount (volume) of the inner layer molten resin 10b. The mold opening operation may be controlled, or conversely, the injection filling amount of the inner layer molten resin 10b in the inner layer resin injection filling process in accordance with the volume expansion amount of the mold cavity 9a due to the mold opening of the movable mold 4 (Volume) may be controlled similarly, or both may be interlocked. In the case where the adhesion between the gate valve 10d and the skin layer 9e of the molten resin 9b for the surface layer is maintained under molding conditions, etc., regardless of the interlocking between the mold cavity expansion process and the inner layer resin injection filling process. The mold cavity expanding step and the inner layer resin injection filling step are not necessarily linked.

  On the other hand, in the case of a mold configuration in which the volume of the mold cavity 9a cannot be expanded (reduced), since there is no mold cavity expansion process, melting of the inner surface of the mold cavity 9a is prevented while preventing resin reversal failure. In order to form a resin flow in the mold cavity 9a so as not to deteriorate the transferability of the resin 9b (first fluid) to the skin layer, the surface layer molten resin 9b in the surface layer resin injection filling step is performed first. Injection filling amount (volume), injection filling pressure, resin temperature, etc., and injection filling timing of inner layer molten resin 10b (second fluid) in the subsequent inner layer resin injection filling step, injection filling amount (volume), As described above, it is necessary to sufficiently examine and adjust the injection filling pressure, the resin temperature, and the like.

  Returning to FIG. The mold cavity expansion process and the inner layer resin injection filling process in FIG. 3A are completed, and the movable mold 4 is opened until the minute mold opening amount L1 is reached, and the volume of the mold cavity 9a is expanded to the product volume. The resulting state is shown in FIG. Subsequently, the seal pin mechanism 10d of the inner layer resin flow path 10c (second fluid flow path) is moved forward to seal the opening portion of the inner layer resin flow path 10c and a predetermined mold clamping force is applied. Shift to a cooling and solidification step for cooling and solidification. Then, after the cooling and solidification of the sandwich molded product 11 formed in the mold cavity 9a and including the inner layer 10 in the surface layer 9 is completed, the movable mold 4 is not shown in FIG. 3C. The mold is opened from the fixed mold 2 by the mold opening / closing mechanism, and the sandwich molded product 11 is taken out of the injection molding machine by the product take-out means (not shown) to complete the molding cycle. At this time point, the surface layer molten resin 9b (first fluid) and the inner layer molten resin 10b (second fluid), which have already been weighed for the next cycle, are respectively surface layer resin flow paths 9c (first fluid). Flow path) and the inner layer resin flow path 10c (second fluid flow path).

  As described above, by repeating the steps from FIG. 2 (a) to FIG. 3 (c), the interior molten resin 10b (second fluid) is surely contained in the surface layer molten resin 9b (first fluid). The sandwich molded product 11 in which the inner layer 10 is included in the surface layer 9 can be continuously formed by filling.

  Here, as in the first embodiment, in the form in which two injection units are connected to the fixed mold 2 or in the form in which one injection unit is connected to the fixed mold 2, a sandwich is generally used. Since the gate mark (gate mark, injection mark) is transferred to the fixed mold 2 side of the molded article 11, the fixed mold 2 side is a non-design surface and the opposed movable mold 4 side is a design surface. Therefore, when the product is taken out, it is extruded from the die by the product extruding means or the like from the fixed die 2 side which is a non-design surface, and is configured as a sandwich molding die for molding the sandwich molded product according to the present invention. As described above, the injection mold is such that two or one injection unit is arranged, two or one injection unit is a fixed mold 2 and a movable mold. 4 is connected, or the effect explained above is due to the difference in form such as which one of the fixed mold 2 side and the movable mold 4 side of the sandwich molded product is a design surface or a non-design surface. There is no significant difference and it can be implemented in such different forms.

  A second embodiment of the present invention will be described with reference to FIGS. FIG. 5 is a schematic sectional view of an injection mold according to Embodiment 2 of the present invention. FIG. 6 is an enlarged view of the tip portion of the seal pin mechanism of the injection mold according to the second embodiment of the present invention. 6A is an enlarged view of the main part A in the second embodiment corresponding to the molding step of FIG. 2C of the first embodiment, and FIG. 6B is a seal pin mechanism in the main part D of FIG. 6A. The skin layer formed at the tip, FIG. 6C is an enlarged view of the main part B in Example 2 corresponding to the molding step of FIG. 3A of Example 1, and the main part D of FIG. The skin layer formed in the seal pin mechanism front-end | tip part in is shown.

  In Example 2, the injection molding die of the present invention is configured as a hollow molding die for molding a hollow molded product having a hollow portion formed therein. The difference between the second embodiment and the first embodiment is that the second fluid is not the inner layer molten resin 10b but a pressurized gas 10b 'for forming a hollow portion therein. On the other hand, for the convenience of explanation, the first fluid is not the surface layer molten resin 9b but the molten resin 9b ', but both are made of a resin material. Therefore, in spite of the difference in the resin molded product to be molded, other molding processes, including the process of injecting the pressurized gas 10b ′ as the second fluid into the molten resin 9b ′ as the first fluid, Since the configurations of the mold and the injection molding machine are basically the same as those in the first embodiment, only differences from the first embodiment will be described.

  Further, in explaining the hollow molding die, a point to be explained on the injection molding machine side with respect to a general-purpose injection molding machine is that a pressurized gas supply means (pressurized gas unit 18 ′) is required. However, there are no other special configuration requirements. Therefore, the description of the injection molding machine is omitted, and only related constituent requirements are described. Here, FIG. 5 and FIG. 6 are also schematic cross-sectional views of only the components necessary for explaining the molding process, such as a mold, like FIG. 1 to FIG. 4 and FIG. Either a longitudinal sectional view (side sectional view) or a transverse sectional view (planar sectional view) along the longitudinal direction of the injection molding machine may be used.

  First, an injection molding die configured as a hollow molding die according to a second embodiment of the present invention will be described with reference to FIG. As shown in FIG. 5, the difference from the injection molding die configured as the sandwich molding die according to the first embodiment of the present invention is not the second injection unit 18 but the pressurized gas unit 18 ′. Is a point to be arranged. Then, since the second fluid that flows into the mold cavity 9a from the pressurized gas unit 18 ′ becomes the pressurized gas 10b ′ instead of the inner layer molten resin 10b, the second fluid channel is changed to the inner layer resin channel 10c. Instead, it is a pressurized gas flow path 10c ′. However, it is the same in that the seal pin mechanism 10d is disposed so as to be able to advance and retract at the opening of the end portion of the pressurized gas passage 10c 'on the mold cavity 9a side. Further, as described above, for the convenience of explanation, the first fluid is not the surface layer molten resin 9b but the molten resin 9b ′, and therefore the surface layer resin flow path 9c is also the resin flow path 9c ′ (first flow path). Fluid flow path).

  Here, also in the second embodiment, as in the first embodiment, the fixed mold 2 and the movable mold 4 are referred to as respective mold dividing surfaces (mold dividing surface, parting surface, and dividing surface). The mold cavity volume is variable by the mold opening / closing operation by the mold opening / closing mechanism of the injection molding machine.

  Next, the pressurized gas unit 18 ', which is one of the differences from the first embodiment, will be described. The pressurized gas unit 18 ′ is a unit that can be used in a hollow portion forming step, which will be described later, and can supply a predetermined amount of gas such as air, nitrogen, carbon dioxide, etc. at a predetermined pressure. The pressure gauge, pressure control valve, gas flow rate control valve, check valve, air release valve, and the like are included. The pressurized gas unit 18 ′ is disposed in the vicinity of the injection molding machine as a unit including a tank unit, and is connected to the pressurized gas flow path 10 c of the fixed mold 2 by a pipe or a gas hose. When pressurized gas can be supplied from utility piping in the factory where the injection molding machine is installed, the pressurized gas is supplied directly from the utility piping, and only necessary piping equipment is separately installed as a unit. A form in which the unit is arranged on a fixed plate of an injection molding machine or the like is also possible.

  Next, with reference to FIGS. 2 to 4 of the first embodiment and referring to FIG. 6, a molding process of a hollow molded article using the injection mold according to the second embodiment of the present invention will be described. The movable mold 4 is moved to the fixed mold 2 side by a mold opening / closing mechanism (not shown) from the mold open state before the start of the molding cycle shown in FIG. 5, and the movable mold 4 and the fixed mold 2 are closed. Thereafter, in a state where the mold clamping force is applied, the gate valve 9d of the resin flow path 9c ′ (first fluid flow path) is opened, and a molten resin that later forms a resin molded body 9 ′ (hollow molded product 11 ′). An injection filling process is performed in which 9b ′ (first fluid) is injected and filled from the injection unit 17 into the mold cavity 9a formed by the movable mold 4 and the fixed mold 2 via the resin flow path 9c ′. . This injection filling process is the same as FIGS. 2B and 2C of Example 1 except for the difference in the designation of the first fluid described above. The case of the mold configuration in which the volume of the mold cavity 9a cannot be reduced (expanded) from the product volume is as described above.

  Here, FIG. 6A is an enlarged view of the main part A in the second embodiment corresponding to the molding step in FIG. 2C of the first embodiment. As described above, the main part D of FIG. 6A, that is, the tip of the seal pin mechanism 10d protruding a predetermined amount in the mold cavity 9a and the molten resin 9b ′ (first fluid) The skin layer 9e is also formed in the contact portion. The skin layer 9e formed in the contact portion between the tip portion of the seal pin mechanism 10d and the molten resin 9b ′ has a seal pin mechanism as shown in FIG. The closer to the tip of the tip portion of 10d, the thinner the thickness of the die cavity 9a, and the strength gradually decreases. The reason is as described above.

  Further, a gas injection nozzle used in a general hollow injection molding method controls injection of pressurized gas into the nozzle, more preferably into the nozzle tip, and backflow of molten resin from the nozzle tip. A gas shut-off / release mechanism is provided to prevent this. Specifically, a slit (cut) of a predetermined length is processed in the nozzle longitudinal direction of the nozzle tip, and normally the gas pressure in the nozzle is kept lower than the pressure in the resin of the molten resin into which the nozzle is inserted. Therefore, when the gas is injected by closing the slit by elastic deformation due to the internal pressure of the resin, the gas pressure in the nozzle is kept higher than the internal pressure of the molten resin into which the nozzle is inserted. A gas blocking / opening mechanism that opens the slit by pressure, and a gas blocking / opening mechanism using a combination of an elastic member such as a spring and a ball are provided. Naturally, gas flow paths communicating with these gas shut-off / release mechanisms are arranged in the nozzle, and in addition to the mechanism for moving the entire nozzle back and forth into the mold cavity, the structure of the gas injection nozzle is complicated, and the nozzle Problems such as blockage due to the backflow of the molten resin to the tip are likely to occur. On the other hand, it is not necessary to incorporate a gas blocking / opening mechanism or a gas flow path communicating with the gas blocking / opening mechanism at the tip of the seal pin mechanism according to the present invention. Further, only the front end portion of the seal pin mechanism 10d is slid in the pressurized gas flow path 10c ′ (second fluid flow path) to block and open / close the opening of the pressurized gas flow path 10c ′. Thus, it is possible to avoid problems such as a complicated structure and a blockage caused by a backflow of molten resin to the nozzle tip.

  Next, during or after the injection filling process, a mold cavity expanding process for expanding the volume of the mold cavity 9a to the product volume is performed. In order to form the hollow portion 10 ′ by causing the seal pin mechanism 10d of the pressurized gas flow path 10c ′ (second fluid flow path) to be retracted simultaneously with the mold cavity expansion step or after a predetermined time has elapsed. The pressurized gas 10b ′ (second fluid) is contacted between the molten resin 9b ′ (first fluid) and the inner surface of the mold cavity 9a from the pressurized gas unit 18 ′ via the pressurized gas channel 10c ′. A hollow portion forming step is performed in which the skin layer (cooled solidified layer) 9e of the molten resin 9b ′ formed on the surface is penetrated and injected into the molten layer 9f in the molten resin 9b ′. This hollow portion forming step corresponds to the inner layer resin injection filling step in the first embodiment. If the second fluid is replaced by the pressurized gas 10b ′ from the inner layer molten resin 10b, it is combined with the previous mold cavity expanding step. This is the same as FIG. 3A and FIG. 3B of the first embodiment.

  Here, the enlarged view of the main part B in Example 2 corresponding to the molding process of FIG. 3A of Example 1 and the skin formed at the tip of the seal pin mechanism 10d in the main part D of FIG. FIG. 6C is a diagram showing the layers. The gas flow of the injected pressurized gas 10b '(second fluid) is converged by the shape of the concave portion that becomes sharper toward the inside of the mold cavity 9a, and the flow pressure is gradually increased. The tip of the gas flow of the pressurized gas 10b ′ whose flow pressure is increased by the flow convergence effect collides with the bottom of the concave portion having the thinnest skin layer 9e and low strength, thereby increasing the pressure. The gas flow of the gas 10b ′ can be caused to penetrate the skin layer 9e of the resin molded body 9 ′ and reliably injected into the molten layer 9f in the molten resin 9b ′ to form the hollow portion 10 ′.

  As in the first embodiment, the interlocking of the mold cavity expanding step and the hollow portion forming step is performed by connecting the tip end portion of the seal pin mechanism 10d of the pressurized gas channel 10c ′ (second fluid channel) and the mold cavity. The state in which the skin layer 9e of the molten resin 9b '(first fluid) formed on the contact surface with the inner surface of 9a is kept in close contact is prevented, and the occurrence of gas ejection in the pressurized gas flow path 10c' is prevented. In addition, the injection resistance of the pressurized gas 10b ′ (second fluid) is lowered while ensuring the formation of the skin layer 9e (cooled solidified layer) of the molten resin 9b ′ and high transferability to the skin layer. It is preferable for preventing the injection of pressurized gas from the skin layer 9e of the molten resin 9b ′, that is, the so-called gas burst failure.

  On the other hand, in the case of a mold configuration in which the volume of the mold cavity 9a cannot be expanded (reduced), there is no mold cavity expansion process as in the first embodiment, so that the mold cavity is prevented while preventing gas burst failure. In order to form a resin flow in the mold cavity 9a so as not to lower the transferability of the molten resin 9b ′ (first fluid) on the inner surface of 9a to the skin layer, the molten resin 9b in the injection filling step performed first is performed. 'Injection filling amount (volume), injection filling pressure, resin temperature, etc., and the injection timing, injection amount (volume), injection pressure of pressurized gas 10b' (second fluid) in the subsequent hollow part forming step Needless to say, it is necessary to sufficiently examine and adjust the pressurized gas temperature and the like.

  Next, similarly to FIG. 3B of the first embodiment, the mold cavity expansion process and the hollow part forming process are completed, and the mold is opened until the movable mold 4 reaches the minute mold opening L1, and the mold cavity is opened. The volume of 9a is expanded to the product volume. Subsequently, the seal pin mechanism 10d of the pressurized gas channel 10c ′ (second fluid channel) is moved forward to seal the opening portion of the pressurized gas channel 10c ′, and a predetermined mold clamping force is applied. It is made to transfer to the cooling solidification process which cools and solidifies in a state. Then, after the cooling and solidification of the hollow molded product 11 ′ formed in the mold cavity 9 a and having the hollow portion 10 ′ formed therein is completed, the movable metal mold is moved in the same manner as in FIG. The mold 4 is opened from the fixed mold 2 by a mold opening / closing mechanism (not shown), and the hollow molded product 11 ′ is taken out of the injection molding machine by a product take-out means (not shown), thereby completing the molding cycle. At this point, the molten resin 9b ′ (first fluid) that has been weighed for the next cycle is held in a flowable state in the resin channel 9c ′ (first fluid channel), and the pressurized gas 10b ′ (second fluid) is also held at a predetermined pressure in the pressurized gas channel 10c ′ (second fluid channel).

  Further, the pressurized gas 10b ′ (second fluid) formed with the hollow portion 10 ′ is pressurized during or after the cooling and solidifying process of the hollow molded article 11 formed in the mold cavity 9a. An atmosphere release valve disposed in a pipe line between the gas flow path 10c ′ (second fluid flow path) and the pressurized gas unit 18 ′ is opened, or an opening portion of the pressurized gas flow path 10c ′ is connected to a seal pin mechanism 10d. Can be made to retreat, open, and discharged.

  As described above, by repeating the steps similar to the steps from FIG. 2A to FIG. 3C of the first embodiment, the pressurized gas 10b ′ (second fluid) is changed into the molten resin 9b ′ (first step). 1 fluid) can be surely injected, and a hollow molded article 11 ′ having a desired hollow portion 10 ′ formed therein can be continuously formed.

  The present invention is not limited to the above embodiment and can be implemented in various forms. In Example 1 and Example 2, it is assumed that the mold cavity expansion process varies the volume of the mold cavity by the mold opening / closing operation by the mold opening / closing mechanism of the injection molding machine, assuming the mold having the shear edge structure. However, the means for changing the volume of the mold cavity is not limited to the mold opening / closing operation by the mold opening / closing mechanism of the injection molding machine, but the volume of the mold cavity such as the moving operation of the movable part in the mold. Any means capable of arbitrarily controlling the volume, variable speed, variable volume holding force (mold position holding force), etc. against the gas pressure in the mold cavity or the resin pressure in the mold cavity. It ’s fine. Further, the present invention is not limited to the shear edge structure, and the present invention can be applied to a mold having a general structure having a mold dividing surface (also referred to as a PL surface) composed only of a plane orthogonal to the mold opening / closing direction. As described above, this is possible.

  Furthermore, the injection mold according to the present invention can be used even when the skin layer (cooled solidified layer) formed on the surface of the molten resin previously injected and filled in the mold cavity is strong. In addition, an injection mold capable of reliably filling and injecting other fluids, and more specifically, an injection mold for sandwich molded products capable of reliably filling the inner layer molten resin into the surface layer molten resin, and The injection molding mold of the hollow molding product capable of forming the desired hollow portion by reliably injecting the pressurized gas into the molten resin, but the molten resin previously injected and filled in the mold cavity The implementation in the case where the skin layer (cooled solidified layer) formed on the surface is not strong is not denied. That is, even when the skin layer is not strong, the thickness of the skin layer is the thinnest and the low-strength portion is changed to the bottom of the recess formed in the skin layer by the tip of the seal pin mechanism. Rather, when the resin flow of the molten resin for the inner layer or the gas flow of the pressurized gas collides with the bottom of the recess, the fluid layer is injected through the molten resin skin layer first. There is no change in the effect that the molten layer in the molten resin can be reliably filled and injected.

9 Surface Layer 9 'Resin Molded Body 9a Mold Cavity 9b Surface Layer Molten Resin (First Fluid)
9b 'Molten resin (first fluid)
9c Surface layer resin flow path (first fluid flow path)
9c 'Molten resin flow path (first fluid flow path)
9e Skin layer (cooled solidified layer)
10 Inner layer 10 'Hollow portion 10b Molten resin for inner layer (second fluid)
10b 'Pressurized gas (second fluid)
10c Inner layer resin flow path (second fluid flow path)
10c ′ Pressurized gas flow path (second fluid flow path)
10d Seal pin mechanism 11 Sandwich molded product 11 ′ Hollow molded product 17 First injection unit 18 Second injection unit 18 ′ Pressurized gas unit

Claims (4)

A first fluid flow path for allowing the first fluid to flow into the mold cavity;
A second fluid flow path for allowing a second fluid to flow into the mold cavity;
The second fluid flow path is movably disposed in an opening portion communicating with the mold cavity,
In the advanced state, the opening portion of the second fluid flow path is sealed, and the tip is protruded into the mold cavity by a predetermined amount.
In the retracted state, the opening portion of the second fluid flow path is opened, and the tip portion is retracted out of the mold cavity.
A seal pin mechanism having a shape in which the shape of the tip portion gradually decreases the cross-sectional area perpendicular to the advance / retreat direction in the advance direction;
Equipped with a,
The concave portion formed in the first fluid by the seal pin mechanism is formed in a contact portion with the tip portion of the seal pin mechanism so as to have a pointed shape toward the inside of the mold cavity, and the flow of the second fluid was allowed to converge in the shape moiety Tsu該尖, injection mold Ru is filled with the second fluid to the first fluid. The first fluid and the second fluid are a molten resin for a surface layer that forms a surface layer and a molten resin for an inner layer that forms an inner layer, respectively.
In the molten resin for the surface layer, the seal pin mechanism is moved forward, and injected and filled from the first fluid flow path into the mold cavity.
The seal pin mechanism is set in a retracted state, and the flow of the molten resin for the inner layer injected and filled from the second fluid flow path into the mold cavity is transferred to the surface of the molten resin for the surface layer and the tip portion of the seal pin mechanism. The concavity formed by the method is converged and filled in the sharp shape portion formed in the contact portion with the tip portion of the seal pin mechanism ,
The injection mold according to claim 1, wherein a sandwich molded product is formed which includes the surface layer and the inner layer, and the inner layer is included in the surface layer. The first fluid and the second fluid are a molten resin and a pressurized gas, respectively;
In the resin molded body formed by causing the seal pin mechanism to move forward and injection filling from the first fluid flow path into the mold cavity,
Wherein by the seal pin mechanism in a retracted state, the flow of the pressurized gas is injected from the second fluid flow path into the mold cavity was formed by the distal end portion of the seal pin mechanism to the molten resin surface A hollow molded article having a hollow portion formed therein is formed by converging and injecting into the sharp shape portion formed at the contact portion of the concave portion with the tip portion of the seal pin mechanism. The injection mold according to claim 1.   The volume of the mold cavity is set to at least a mold opening / closing operation by a mold opening / closing mechanism of an injection molding machine to which the injection molding die is attached, and a moving operation of a movable part arranged in the injection molding die. The mold for injection molding according to any one of claims 1 to 3, wherein the mold is expanded / reduced by one.

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