JP5395135B2 - Injection molding equipment for thermosetting resin - Google Patents

Description

  The present invention relates to an injection molding apparatus used for a thermosetting resin and a method for producing a molded product using the same.

  Conventionally, in an injection molding apparatus for a thermosetting resin, various techniques have been studied in order to prevent curing of a liquid molding material staying in a nozzle. For example, Patent Document 1 discloses a technique for preventing a liquid molding material from being hardened due to overheating of a nozzle by providing a heat insulating layer on a mold. Patent Document 2 discloses a technique for cooling a nozzle with water. Furthermore, patent document 3 discloses the heat insulation part which seals the gap | interval of a metal mold | die and a nozzle.

JP-A-9-286046 JP 2000-280290 A Japanese Patent Laid-Open No. 5-13889

  However, in the technique disclosed in Patent Document 1, since the heat insulating layer is always in contact with the mold, the heat insulating layer is gradually heated while continuously performing injection molding. Therefore, when the nozzle comes into contact with the high-temperature heat insulating layer at the time of injection, the temperature of the nozzle rises, and there is a possibility that the increase in viscosity (curing) due to the reaction of the thermosetting liquid molding material cannot be prevented. Further, there is a possibility that the temperature of the nozzle rises due to heat radiated from the mold. Further, since there is no mechanism for preventing leakage of the thermosetting liquid molding material between the nozzle and the mold, there is a possibility that the thermosetting liquid molding material leaks from the gap between the two. Even when the water-cooling nozzle described in Patent Document 2 is combined with the technique disclosed in Patent Document 1, since the heat insulating layer cannot be cooled by cooling water, there is a possibility that cooling of the tip portion of the nozzle is particularly insufficient. . In addition, the thermosetting liquid molding material cannot be prevented from leaking from the gap between the nozzle and the mold. Further, as disclosed in Patent Document 3, the form in which the opening at the tip of the nozzle is in direct contact with the mold gate may result in insufficient heat insulation.

  The present invention has been made in order to solve the above-described problems, and prevents the thermosetting liquid molding material from being cured due to overheating of the nozzle, and also provides a thermosetting liquid molding material from the gap between the nozzle and the mold. It aims at providing the injection molding apparatus for thermosetting resins which can prevent leaking, and the manufacturing method of the molded article by this.

  To achieve the above object, the present invention is an injection molding apparatus for a thermosetting resin having a nozzle for injecting a thermosetting liquid molding material, the nozzle for supplying the thermosetting liquid molding material. A nozzle body in which a material supply path is formed, a sealing member having heat insulation and attached to the nozzle body, a cylindrical member into which the nozzle body is inserted and supporting the nozzle body. The stop member has a communication path communicating with the material supply path.

  Furthermore, in the above aspect, the present invention is provided with a detachable cap for fixing the sealing member, a cooling water groove for flowing cooling water through the nozzle body, and the nozzle body and the cylindrical member. The cooling water sealing member for sealing the cooling water that has entered the gap between the nozzle body and the sealing member abuts on the mold, seals the gap between the nozzle body and the mold, and The communication path communicates with the inflow path in the mold of the thermosetting liquid molding material, or the sealing member is detached from the mold in a standby state other than when the thermosetting liquid molding material is injected and molded. Features.

  ADVANTAGE OF THE INVENTION According to this invention, the heat insulation effect of the sealing member which has heat insulation can be heightened further by the structure of a cooling mechanism and a sealing member. Therefore, the temperature rise of the nozzle can be suppressed, and the local thermosetting liquid molding material can be prevented from being cured in the material supply path. Furthermore, when the thermosetting liquid molding material is injected into the cavity space, the gap between the mold and the nozzle is sealed by the sealing member, so that the thermosetting liquid molding material can be prevented from leaking. Further, the sealing member can be easily fixed to the cylindrical member by the cap.

  Furthermore, according to the present invention, a molding cycle for injection molding a molded product of a thermosetting resin can be continuously performed by a heat insulating effect and a sealing effect.

Sectional drawing which shows the structure of the injection molding apparatus by one Embodiment of this invention. The assembly perspective view which shows the structure of a nozzle. Sectional drawing which shows a mold open state in the same injection molding apparatus. Sectional drawing which shows a mold closed state in the same injection molding apparatus. Sectional drawing which shows the state with which the thermosetting liquid molding material is filled in a metal mold | die from a nozzle in the same injection molding apparatus.

  An injection molding apparatus for a thermosetting resin according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows the configuration of an injection molding apparatus. The injection molding apparatus 1 includes a thermosetting liquid molding in a fixed mold 2, a movable mold 3 movable with respect to the fixed mold 2, and a cavity space 7 defined by the fixed mold 2 and the movable mold 3. It is constituted by a nozzle 4 and the like for injecting the material 8. The fixed mold 2 has a fixed mold main body 21 and a sprue bush 22 with which the nozzle 4 comes into contact. In the present embodiment, the sprue bushing 22 is attached to the fixed mold main body 21 with the screw 23, but may be formed integrally with the fixed mold main body 21. The fixed mold 2 and the moving mold 3 are heated to about 80 ° C. to 170 ° C., and the thermosetting liquid molding material 8 filled in the cavity space 7 is cured and molded.

  FIG. 2 shows the configuration of the nozzle 4. The nozzle 4 includes a nozzle main body 41 in which a material supply path 41 a for supplying the thermosetting liquid molding material 8 is formed, and an O-ring 42 (cooling water) mounted in a ring mounting groove 41 d near the tip of the nozzle main body 41. Sealing member), a cylindrical member 43 that supports the nozzle body 41, a sealing member 44 that is attached to the tip of the cylindrical member 43, and a member for fixing the sealing member 44 to the tip of the cylindrical member 43. It is constituted by a cap 45 or the like.

  In the nozzle body 41, a material supply path 41a, a cooling water groove (forward path groove) 41b in which cooling water for cooling the nozzle 4 is circulated, a cooling water groove (return path groove) 41c, and a cooling water groove (communication groove) are provided. 41e, a ring mounting groove 41d in which the O-ring 42 is mounted, and the like are formed. The material supply path 41a is formed through the inside of the nozzle body 41 (see FIG. 1). The forward groove 41b, the return groove 41c, the communication groove 41e, and the like constitute a cooling mechanism for the nozzle body 41. The forward groove 41b is formed in a spiral shape from the root portion to the tip portion of the nozzle body 41, and the return groove 41c is formed in a spiral shape from the tip portion to the root portion of the nozzle body 41. The forward groove 41b and the backward groove 41c are communicated with each other by a communication groove 41e formed at the tip of the nozzle body 41.

  The forward groove 41b and the return groove 41c are alternately formed on the outer surface of the nozzle body 41, that is, in a two-row spiral shape. Cooling water (cold water) supplied via the cylindrical member 43 flows through the cooling water channel surrounded by the outward groove 41 b and the inner surface of the cylindrical member 43. On the other hand, cooling water (warm water) heated by heat exchange with the nozzle body 41 and the like flows into the cooling water channel surrounded by the return groove 41 c and the inner surface of the cylindrical member 43, and passes through the cylindrical member 43. Discharged. While cooling water flows through the forward groove 41b, the communication groove 41e, and the return groove 41c, heat exchange is performed with the nozzle body 41 and the like, and the temperature at which the nozzle body 41 and the like does not cure the thermosetting liquid molding material 8 in a short time. Until cooled. The cooling water that has entered the gap between the nozzle body 41 and the cylindrical member 43 is sealed by the O-ring 42 that is mounted in the ring mounting groove 41 d and does not leak out of the nozzle 4.

  A cold water supply water channel 43a for supplying cooling water (cold water) to the cooling water channel surrounded by the forward channel 41b and the inner surface of the cylindrical member 43, and a return channel 41c and a cylinder are provided at the root of the cylindrical member 43. A hot water discharge channel 43 b for discharging cooling water (hot water) to the outside of the nozzle 4 from the cooling channel surrounded by the inner surface of the member 43 is formed. The cold water supply channel 43 a and the forward channel 41 b and the hot water discharge channel 43 b and the return channel 41 c are communicated with each other at the root portion of the cylindrical member 43.

  A communication hole 44 a (communication path) that communicates with the material supply path 41 a of the nozzle body 41 and the material supply path 22 a (inflow path) of the sprue bush 22 is formed at the center of the sealing member 44. The sealing member 44 is sufficient to limit the amount of heat exchanged between the sprue bushing 22 and the nozzle body 41 within a unit time and to suppress the curing of the thermosetting liquid molding material 8 in the material supply path 41a. The heat-insulating material is formed of a material having sufficient elasticity to prevent leakage of the thermosetting liquid molding material 8 from the gap between the sprue bush 22 and the nozzle body 41. Examples of the material for forming the sealing member 44 include polymer materials having excellent chemical resistance and heat resistance such as polyamide, polyester, and ethylene fluoride. The sealing member 44 is set to a sufficient thickness (for example, about 1 to 5 mm) to ensure the heat insulation and elasticity, and is fixed to the distal end portion of the cylindrical member 43 by a cap 45. A male screw for mounting the cap 45 is formed at the tip of the cylindrical member 43. When the nozzle 4 is brought into contact with the sprue bushing 22, a large force is generated in the direction opposite to the arrow B (see FIG. 4), so that the cap 45 is fixed with a so-called double nut as necessary. . When the nozzle body 41 is inserted into the cylindrical member 43, the tip of the nozzle body 41 is in close contact with the sealing member 44.

  Hereinafter, the operation of the injection molding apparatus 1 will be described with reference to FIGS. 3 to 5. In the standby state shown in FIG. 3, the moving mold 3 is separated from the fixed mold 2, and the nozzle 4 is also separated from the fixed mold 2. Further, the needle valve 47 provided in the material supply path 41 a of the nozzle body 41 is closed, and the thermosetting liquid molding material 8 is sealed by the tip portion of the needle valve 47. First, as indicated by an arrow A, the moving mold 3 is moved in the direction of the fixed mold 2 and the mold is closed. In this state, the sprue bush 22 and the sealing member 44 are separated (standby state), and heat exchange is not performed between them.

  Thereafter, as indicated by an arrow B in FIG. 4, the nozzle 4 is moved in the direction of the fixed mold 2. As a result, the sprue bush 22 and the sealing member 44 come into contact with each other and come into close contact with each other. At this time, since the temperature of the sprue bushing 22 is equivalent to that of the high temperature fixed mold 2, heat exchange is started between the high temperature sprue bushing 22 and the low temperature nozzle 4. In the present embodiment, since the sealing member 44 having heat insulation is interposed between the nozzle body 41 and the sprue bushing 22, the nozzle is within the time when the sprue bushing 22 and the sealing member 44 are in contact with each other. The amount of heat exchanged between the main body 41 and the sprue bushing 22 is extremely limited.

  Thereafter, as indicated by an arrow C in FIG. 5, the needle valve 47 is opened, and the thermosetting liquid molding material 8 retained in the material supply path 41 a of the nozzle body 41 flows into the cavity space 7. The thermosetting liquid molding material 8 that has flowed into the cavity space 7 is heated and cured by the fixed mold 2 and the movable mold 3. On the other hand, the thermosetting liquid molding material 8 retained in the material supply path 41a of the nozzle body 41 has the nozzle body 41 and the sprue bush 22 thermally insulated by the sealing member 44, and the nozzle body. 41 is cooled by the cooling water flowing through the forward groove 41b, the communication groove 41e, and the return groove 41c, so that the fluidity of the thermosetting liquid molding material 8 is maintained.

  When the thermosetting liquid molding material 8 in the cavity space 7 is cured, the needle valve 47 is closed, the nozzle 4 is detached from the fixed mold 2 and returns to the standby state. Thereby, the contact between the sprue bush 22 and the sealing member 44 is released, and the sealing member 44 is cooled by the cooling water together with the nozzle body 41. Thereafter, the moving mold 3 is opened, the molded product formed in the cavity space 7 is released, and one molding cycle is completed.

  As described above, according to the injection molding device 1 of the present embodiment, since the sealing member 44 having heat insulation is provided at the contact portion between the nozzle body 41 and the sprue bushing 22, it is thermosetting. When the liquid molding material 8 is injected into the cavity space 7, heat conduction from the sprue bushing 22 can be suppressed. Further, since the sealing member 44 having heat insulation is provided on the nozzle 4 side, the contact state between the sprue bushing 22 and the sealing member 44 is in a standby state when the nozzle 4 is detached from the sprue bushing 22. It will be solved. As a result, heat conduction from the sprue bushing 22 to the sealing member 44 in the standby state is temporarily interrupted, and further, the sealing member 44 is cooled by the cooling mechanism of the nozzle body 41, so that the heat insulating effect of the sealing member 44 is achieved. Can be increased. Further, since the heat radiated from the fixed mold 21 to the tip of the nozzle body 41 can be shielded by the sealing member 44, the temperature rise of the nozzle body 41 is suppressed and the thermosetting liquid molding material 8 is prevented from being cured. be able to. Further, when the thermosetting liquid molding material 8 is injected into the cavity space 7, the gap between the sprue bush 22 and the nozzle body 41 is sealed by the sealing member 44, so that the thermosetting liquid molding material 8 leaks. Can be prevented.

  Further, since the nozzle body 41 and the sealing member 44 are cooled by the cooling water flowing through the cooling water grooves 41b, 41c, 41e, the curing of the thermosetting liquid molding material 8 in the material supply path 41a is further prevented. Can do. Further, since the sealing member 44 is mounted on the nozzle body 41, the sealing member 44 and the nozzle body 41 are cooled by the cooling water even after the contact state between the sprue bush 22 and the sealing member 44 is released. It will be cooled. As a result, the temperature of the sealing member 44 can be continuously decreased until the sealing member 44 comes into contact with the sprue bushing 22 in the next molding cycle, and the heat insulating effect of the sealing member 44 is further enhanced. Can do. Moreover, since the cooling water grooves 41b, 41c, and 41e are provided on the outer surface of the nozzle body 41, the cooling water grooves 41b, 41c, and 41e can be easily formed by cutting the nozzle body 41. . Further, since the cooling water grooves 41b and 41c are formed in a spiral shape, the entire nozzle body 41 can be cooled uniformly, and the local thermosetting liquid molding material 8 can be cured in the material supply path 41a. It becomes possible to prevent. Further, the cooling water grooves 41 b and 41 c communicate with the forward groove 41 b formed from the root portion of the nozzle body 41 to the distal end portion, and communicate with the forward groove 41 b at the distal end portion, and from the distal end portion of the nozzle body 41 to the root portion. And the return passage groove 41c formed over the portion, and formed in two strips, the entire nozzle body 41 can be further uniformly cooled, and the local heat in the material supply passage 41a Curing of the curable liquid molding material 8 can be prevented.

  In addition, this invention is not restricted to the structure of the said embodiment, What is necessary is just to thermally insulate at least the nozzle 4 and the fixed metal mold | die 2 or the moving metal mold 3 with the sealing member 44 which has heat insulation. The present invention can be modified in various ways. For example, the shapes of the cooling water grooves 41b and 41c are not limited to those shown in FIG. 2, and can be appropriately set according to the temperature of the nozzle 4. it can. The configuration of the sealing member 44 may be a three-layer structure in which a heat insulating layer made of a material having excellent heat insulating properties is sandwiched between elastic layers made of a highly elastic material. In this case, the heat insulating effect and sealing effect of the sealing member 44 can be further enhanced.

1 injection molding equipment,
2 fixed mold,
3 Moving mold,
4 nozzles,
8 Thermosetting liquid molding material,
22 Sprue bushing 22
22a Material supply path (inflow path)
41 Nozzle body,
41a Material supply path 41b Cooling water groove (outward groove),
41c cooling water groove (return groove),
42 O-ring (cooling water sealing member)
43 tubular member,
44 sealing member,
44a Communication hole (communication passage)

Claims (5)

In an injection molding apparatus for a thermosetting resin provided with a nozzle for injecting a thermosetting liquid molding material,
The nozzle includes a nozzle body in which a material supply path for supplying a thermosetting liquid molding material is formed, a sealing member that has heat insulation and is attached to the nozzle body, and the nozzle body is inserted. A cylindrical member that supports the nozzle body,
The said sealing member has a communicating path connected with the said material supply path, The injection molding apparatus for thermosetting resins characterized by the above-mentioned.   The thermosetting resin injection molding apparatus according to claim 1, wherein a removable cap for fixing the sealing member is attached to the cylindrical member. The nozzle body has a cooling water groove formed in a spiral shape for flowing cooling water for cooling the nozzle on the outer surface thereof.
Cooling water that has entered the gap between the nozzle body and the tubular member is sealed between the cooling water groove and the sealing member and on the contact surface between the nozzle body and the tubular member. An injection molding apparatus for a thermosetting resin according to claim 1 or 2, wherein a cooling water sealing member is attached. A mold for defining a cavity space into which the thermosetting liquid molding material is injected;
The sealing member abuts on the mold, and the nozzle is interposed between the nozzle body and the mold when the nozzle injects a thermosetting liquid molding material into the cavity space and molds the nozzle. Sealing the gap between the body and the mold,
4. The injection molding for thermosetting resin according to claim 1, wherein the communication path communicates with an inflow path in the mold through which the thermosetting liquid molding material flows into the cavity space. apparatus. From the standby state in which the mold is opened and the nozzle is separated from the mold, the mold is closed and the mold and the sealing member are in a standby state,
A step in which the sealing member is brought into contact with and in close contact with the mold that is closed;
A step in which the thermosetting liquid molding material retained in the material supply path of the nozzle body flows into the cavity space;
A step in which the thermosetting liquid molding material is heated and cured by the mold,
The nozzle is detached from the mold and returned to a standby state;
And a step of releasing the molded product formed in the cavity space by opening the mold released from contact with the sealing member. A method for producing a thermosetting resin molded article, comprising: an injection molding apparatus according to claim 1;

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