JP2004243545A - Injection mold and runner holder - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an injection mold capable of certainly holding a runner material when a molded product and the runner material are separated and capable of easily removing the runner material without using a runner stripper plate when the runner material separated from the molded product is removed. <P>SOLUTION: This injection mold is constituted by interpolating a shaft body in a base plate so that one end side of the shaft body is movable in the spaced-apart direction of a template so as to be taken in and out from the close contact surface of a base plate on one side of the template corresponding to the forming position of a runner part. The shaft body is prevented from being pulled out toward the close contact surface of the base plate and embedded in the base plate on its one end side when a resin flows within the runner part. A holding groove, of which the opening part permitting the inflow of the resin from the runner part is provided to one end surface of the shaft body, is formed to the region taken in and out from the close contact surface. The holding groove is set in its shape so as not only to prevent the resin solidified after inflow from moving in the spaced-apart direction of one template but also to make the solidified resin separable toward the opening of the holding groove. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a mold for injection molding and a runner holder for holding a runner material for separating a molded product from the runner material.
[0002]
[Prior art]
BACKGROUND ART Conventionally, various injection molding dies have been provided for molding molded articles. As shown in FIG. 6, a pair of mold plates 51a and 51b which form a molding space 50 by clamping the mold, and are attached to an injection port of an injection molding machine, and the molten resin is injected from the injection port as shown in FIG. Is mainly provided with a mounting plate 53 provided with a first sprue portion 52 into which is injected, and a runner stripper plate 54 interposed between the mounting plate 53 and one of the mold plates 51a.
[0003]
One of the pair of mold plates 51a and 51b has a mold (cavity or core) for forming the molding space 50 on one surface, and the first sprue on the other surface. A runner groove 56 for forming a runner portion 55 communicating with the portion 52 is formed. Further, a second sprue portion for communicating the molding space 50 with the runner portion 55 when the pair of mold plates 51a and 51b is closed. 57 are formed.
[0004]
In the injection molding die, the mounting plate 53, the runner stripper plate 54, and the pair of mold plates 51a and 51b are brought into close contact with each other, so that the runner groove 56 is brought into close contact with the one mold plate 51a and the runner stripper plate 54. The runner 55 is a resin flow path, and the runner 55 communicates the first sprue 52, the second sprue 57, and the molding space 50 to form a resin flow path.
[0005]
Such an injection molding die includes, when a molded product P is molded using the injection molded mold, a molded product P molded in the molding space 50 and a resin R solidified in a flow path (hereinafter, runner). Material). Specifically, by separating the pair of mold plates 51a and 51b from the runner stripper plate 54 in a state where the resin in the molding space 50 and the flow path is solidified, the connection between the runner material R and the molded product P is formed. A tensile force acts on the molded product P and the runner material R solidified by the second sprue portion 57 is separated at a connection portion.
[0006]
As described above, the injection molding die holds the runner material R when the mold plates 50a and 50b separate from the runner stripper plate 54 so as to apply a tensile force to the connection portion between the runner material R and the molded product P. Holding pin 58 is provided.
[0007]
When the holding pin 58 is loosely inserted into the runner stripper plate 54, the base end is fixed to the mounting plate 53, and the tip end is formed by one of the mold plate 50 a and the runner stripper plate 54. It is provided so as to be located in the portion 55. The distal end located in the runner portion 55 is shaped so that the diameter increases from the base end toward the distal end.
[0008]
As a result, the runner material R located in the runner portion 55 is solidified with the tip of the holding pin 58 wrapped around, and when one of the mold plates 51a is separated from the runner stripper plate 54, Will be retained. Therefore, a tensile force can be applied to a portion (the portion formed in the second sprue portion 57) connecting the molded product P and the runner material R, and the molded product P and the runner material R can be separated. Become.
[0009]
Further, the injection molding die can release the runner R from the holding pin 58 and remove the runner R. Specifically, by separating the runner stripper plate 54 from the mounting plate 53, the runner stripper plate 54 pushes out the runner material R corresponding to the runner portion 55 in the separating direction. Then, in the runner material R, a portion (a hole formed according to the shape of the tip portion) in an engagement state with the tip portion of the holding pin 58 expands, and finally the runner material R is held. The runner material R can be removed from the tip of the use pin 58.
[0010]
[Problems to be solved by the invention]
However, as described above, in the injection molding die having the above-described configuration, since the runner R is held by the tip of the holding pin 58 being caught in the runner R, the tip of the holding pin 58 is held. Therefore, the runner R could not be easily removed from the holding pin 58 without using the runner stripper plate 54. Therefore, the runner stripper plate 54, a driving device for operating the runner stripper plate 54, and the like are required, and the structure of the injection mold is complicated. Further, there is also a problem that the impact sound due to the operation of the run stripper plate 54 and the positioning operation when stopping the runner stripper 54 impairs the working environment.
[0011]
Therefore, the present invention, in view of such circumstances, when separating the molded product and the runner material, while reliably holding the runner material, when removing the runner material separated from the molded product, An object of the present invention is to provide an injection molding die and a runner holder that can easily remove a runner material without using a runner stripper plate.
[0012]
[Means for Solving the Problems]
An injection molding die according to the present invention, as described in claim 1, includes a pair of mold plates that form a molding space by clamping a base plate having a first sprue portion into which a resin is injected. The first sprue portion and the second sprue portion communicate with each other between the close contact surfaces of the one mold plate and the base plate by bringing one mold plate having the second sprue portion communicating with the molding space into close contact. The runner portion is configured to be formed, and by separating the template from the base plate, the molded product molded in the molding space and the runner material present in the runner portion are configured to be separated. In the injection molding die, the base plate is separated from the mold plate in a direction corresponding to the formation position of the runner portion so that one end side can be protruded and retracted from the close contact surface of the base plate to the mold plate side. The shaft is movably inserted into the shaft, and the shaft is The stopper is prevented from coming off to the contact surface side, and one end side is configured to be buried in the base plate when the resin flows in the runner portion. A holding groove having an opening portion on one end surface of the shaft body through which the resin can flow is formed, and the holding groove prevents the resin that has flowed in and solidified from moving in the separating direction of one of the mold plates. The solidified resin is shaped so as to be detachable from the opening side of the holding groove. Note that, when the resin flows in the runner portion, the one end side is buried in the base plate, and includes a state in which one end side is buried before the resin flows, and a state in which one end side is buried after the flow of the resin starts. It is a concept. The opening of the holding groove refers to an opening formed on the outer peripheral surface of the shaft body.
[0013]
According to the above-mentioned injection mold, at a position corresponding to the formation position of the runner portion, the mold plate can be moved in the separating direction of the mold plate so that one end side can protrude and retract from the close contact surface of the base plate to one mold plate side. The shaft body is inserted into the base plate, and the shaft body is configured so that one end side is buried in the base plate when the resin flows in the runner portion, and the shaft body is protruded from the close contact surface. Since the holding groove having an opening on one end surface of the shaft body through which the resin from the runner part can flow is formed, the molten resin flowing into the runner part is buried in the base plate. Flows into the holding groove through the open portion on one end surface of the holding groove and is filled.
[0014]
The holding groove is shaped so as to prohibit the resin that has flowed in and solidified from moving in the separating direction of the one mold plate, and has such a shape that the solidified resin can be detached to the opening side of the holding groove. Therefore, the resin filled in the holding groove is connected to the runner material in the runner portion and solidified in the holding groove without moving in the direction in which one of the mold plates is separated. Further, the resin in the holding groove in this state is solidified in a shape that can be separated from the opening side of the holding groove, but since the shaft body is buried in the base plate, the resin in the outer circumferential surface of the shaft body is The separation is prevented by the opposing surfaces.
[0015]
Then, the mold plate is separated from the base plate in order to separate the molded product formed by solidifying the molten resin in the molding space and the runner material solidified in the second sprue portion and the runner portion. The runner material connected to the molded product of the above is about to move in the direction of separating the template.
[0016]
Then, since the resin of the holding groove is solidified in a shape that does not move in the separating direction of the template in the holding groove, one end of the shaft body is pulled out from inside the base plate to one template side, and the holding groove in the shaft body Is exposed on one template side.
[0017]
Then, when the shaft body is prevented from coming off to the close contact surface side of the base plate, the resin of the holding groove moves in the holding groove in the separating direction of the template as described above. When the mold plate is further separated from the base plate, the pulling force is concentrated on the connecting portion between the molded product and the runner material, and the molded product is separated from the runner material. Become.
[0018]
Then, the portion formed by the second sprue portion in the runner material that has been supported by being connected to the molded product in the pair of template plates becomes the free end. Then, as described above, all of the holding grooves shaped so that the solidified resin can be detached to the opening side are exposed, so if the runner material is moved from the axis of the shaft body toward the opening direction of the holding groove, The resin solidified in the runner material holding groove can be released.
[0019]
As described above, when the injection mold according to the present invention is employed, when the molded product and the runner material are separated from each other, the runner material can be reliably held, while the runner separated from the molded product is separated. At the time of removing the material, it is possible to obtain an effect that the runner material can be easily removed without using the runner stripper plate.
[0020]
Therefore, the configuration of the injection mold can be simplified, that is, the number of parts can be reduced. Further, when separating the molded product from the runner material, it is possible to prevent the generation of an impact sound that harms the working environment.
[0021]
Further, in the injection molding die according to the present invention, the shaft body is buried in the base plate when the resin flows in the runner portion. In the runner portion, there is no obstruction to the flow of the resin, the molten resin injected in the runner portion flows smoothly, and the molten resin can be guided to the second sprue portion and the molding space. Functions and effects can be obtained.
[0022]
Further, it is preferable that the base plate is provided with a biasing means for biasing the shaft body toward the template side. By doing so, the resin flowing from the runner portion enters between the inner peripheral surface of the hole into which the shaft is inserted and the outer peripheral surface of the shaft, and separates the molded product from the runner material. Even if the movement of the shaft body becomes worse, the urging force of the urging means assists the movement of the shaft body, and the movement of the shaft body can be made smooth.
[0023]
Furthermore, as described in claim 3, it is also possible to adopt a configuration in which a plurality of the shafts are provided, and each shaft is restricted from rotating around the axis with the holding grooves directed in the same direction. . By doing so, even if the runner portion is formed radially starting from a certain point or formed long, the runner portion can be held at a plurality of locations. In addition, when the runner material is removed, the solidified resin can be easily separated from each holding groove because each holding groove faces in the same direction.
[0024]
Furthermore, the runner holder according to the present invention, as described in claim 4, forms a molding space by clamping a base plate having a first sprue portion into which resin is injected. The first sprue portion and the second sprue portion communicate with each other between the close contact surfaces of the one mold plate and the base plate by closely contacting one template provided with the second sprue portion communicating with the molding space. A molded product is molded by an injection molding die configured so that a runner portion is formed, and a mold plate is separated from a base plate to separate a molded product in the molding space and a runner material present in the runner portion. A runner holder for holding the runner material when separated, a tubular body buried in the base plate with one end opening corresponding to the formation position of the runner portion, the one end opening being aligned with the close contact surface of the base plate, and the one end side being cylindrical. Be able to emerge from one end opening of the body , A shaft body movably inserted into the cylindrical body, the shaft body is prevented from falling off to the one end opening side of the cylindrical body, and when the resin flows in the runner portion One end side is configured to be buried in the cylindrical body, and further, has an open portion on one end surface of the shaft body at a portion protruding and retracting from one end opening of the cylindrical body, through which resin from the runner portion can flow. A holding groove is formed, and the holding groove is shaped so as to prohibit the resin that has flowed in and solidified from moving in the separating direction of the one mold plate, and the solidified resin is placed on the opening side of the holding groove. It is characterized in that it is configured to be detachable. Note that, when the resin flows in the runner portion, one end side is buried in the cylindrical body, and includes a state in which one end side is buried before the resin flows, and a state in which one end side is buried after the flow of the resin starts. It is a concept. The opening of the holding groove refers to an opening formed on the outer peripheral surface of the shaft body.
[0025]
According to the above-mentioned runner holder, a tubular body buried in the base plate with one end opening corresponding to the formation surface of the runner portion and the close contact surface of the base plate, and one end side protruding and retracting from one end opening of the tubular body. A state in which one end of the cylindrical body is buried in the cylindrical body when the resin flows in the runner portion while being prevented from falling off to the one end side of the cylindrical body so that the resin can flow. A holding groove having an open portion on one end surface of the shaft body is formed at a portion of the shaft body that protrudes and retracts from one end surface of the cylindrical body to the outside. Therefore, if the one end opening of the cylindrical body is buried so as to match the close contact surface of the base plate, and the runner holder having the above configuration is attached to the base plate, the molten resin flowing into the runner portion can be removed from the cylindrical body (base). The open part at one end face of the shaft body buried in the And so that the filling flow into the holding groove by.
[0026]
The holding groove is shaped so as to prohibit the resin that has flowed in and solidified from moving in the separating direction of the template, and the solidified resin is shaped so as to be detachable to the opening side of the holding groove. Therefore, the resin filled in the holding groove is connected to the runner material in the runner portion and solidifies in the holding groove without moving in the separating direction of the template. Further, the resin in the holding groove is solidified in a shape that can be detached to the opening side of the holding groove, but since the shaft is buried in the base plate, the surface facing the outer peripheral surface of the shaft is As a result, the state is prevented from being detached.
[0027]
In this state, when the mold plate is separated from the base plate in order to separate the molded product formed by solidifying the molten resin in the molding space and the runner material solidified in the second sprue portion and the runner portion, the molding is performed. The runner material connected to the molded product in the space tries to move in the direction in which the template is separated.
[0028]
Then, since the resin of the holding groove is solidified in a shape that does not move in the separating direction of the template in the holding groove, the shaft body is pulled out from the base plate to the template side, and the portion of the shaft body where the holding groove is formed is formed. All will be exposed on one template side.
[0029]
Then, when the stopper is acted on the shaft body that has been prevented from falling off to the one end opening side of the cylindrical body, as described above, the resin of the holding groove is moved in the separating direction of the template in the holding groove. When the mold plate is further separated from the base plate because it is solidified without moving, the pulling force concentrates on the joint between the molded product and the runner material, and the molded product separates from the runner material. It becomes.
[0030]
Then, the portion formed by the second sprue portion in the runner material that has been supported by being connected to the molded product in the pair of template plates becomes the free end. In this state, since all the holding grooves are exposed, the resin solidified in the holding grooves can be released by moving the runner material from the axis of the shaft toward the opening direction of the holding grooves. .
[0031]
As described above, the runner holder according to the present invention, by attaching to the base plate, the injection molding die having a pair of mold plates, when separating the molded product and the runner material, the runner material While it is possible to reliably hold the runner material, it is possible to obtain an effect that the runner material can be easily removed without using the runner stripper plate when removing the runner material separated from the molded product.
[0032]
Therefore, when separating the molded product from the runner material, it is also possible to prevent the generation of an impact sound that harms the working environment.
[0033]
Further, in the injection molding die according to the present invention, the shaft body is buried in the base plate when the resin flows in the runner portion. In the runner portion, there is no obstruction to the flow of the resin, the molten resin injected in the runner portion flows smoothly, and the molten resin can be guided to the second sprue portion and the molding space. Functions and effects can be obtained.
[0034]
Further, as set forth in claim 5, it is preferable that an urging means for urging the shaft body to one end side is provided inside the cylinder main body of the holder. By doing so, when the tubular body is embedded in the base surface and the runner holder is attached, the resin flowing from the runner portion is formed on the inner peripheral surface of the tubular body and the outer peripheral surface of the shaft. Even if the movement of the shaft body deteriorates when separating the molded product and the runner material, the urging force of the urging means will assist the movement of the shaft body, The movement can be smooth.
[0035]
Furthermore, it is preferable that the shaft body is restricted from rotating around the axis. By doing so, the injection molding die to which the runner holder is attached is provided with a runner portion formed radially or elongate from a certain point as a starting point, and a runner portion of the runner portion is provided. Even when a plurality of runner holders are attached so as to hold the material at a plurality of positions, it is possible to prevent the direction of the holding groove of the shaft from being changed, and the runner material can be easily removed.
[0036]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to the accompanying drawings.
[0037]
As shown in FIG. 1, the injection mold according to the present embodiment includes a base plate 2 provided with an injection channel 1 for injecting a molten resin, and a molding space 3 for molding a molded product P by clamping. It has a pair of template plates 4a and 4b formed between the opposing surfaces, and these are arranged so as to form a laminated state, and can be separated from each other.
[0038]
The base plate 2 is a metal plate, and one surface thereof is configured to be connectable to a nozzle portion of the injection molding machine, and from one surface to the other surface so as to correspond to the nozzle position of the injection molding machine. The injection flow path 1 penetrating toward is formed.
[0039]
The injection flow path 1 is a part of a flow path for feeding the molten resin injected (injected) from the injection molding machine into the molding space 3, is formed on one surface side, and is provided with a nozzle of the injection molding machine. And a first sprue portion 6 formed on the other surface in communication with the nozzle connection portion 5.
[0040]
The nozzle connection portion 5 has an opening corresponding to the nozzle of the injection molding machine on one surface, and has a substantially frusto-conical shape in which the inner diameter is smaller on one surface side of the base plate 2 than on the other surface side. The inner peripheral surface of the small diameter portion is formed so that the nozzle head of the injection molding machine can abut. Here, the frusto-conical shape refers to the shape of the remaining portion obtained by cutting the conical shape in a direction perpendicular to the axis and removing the toe side.
[0041]
The first sprue portion 6 has an opening having a smaller diameter than the opening of the nozzle connecting portion 5 on the other surface of the base plate 2, and the inner diameter becomes smaller on one surface side as compared with the other surface side, so that the first sprue portion 6 is cut off. It is formed in a conical shape, and the small diameter side is connected to the small diameter portion of the nozzle connection part 5 so as to communicate with the nozzle connection part 5.
[0042]
The base plate 2 has a flow path (runner portion 7) communicating with the first sprue portion 6 between the close surfaces, because one surface of one mold plate 4a is in close contact with the other surface of the base plate 2. Is formed. In addition, the injection molding die according to the present embodiment is configured to be able to take a plurality of molded products P, and accordingly, the runner portion 7 starts from a position corresponding to the first sprue portion 6 in a plan view. A plurality is formed radially.
[0043]
The base plate 2 has an insertion hole 9 for inserting a shaft 8 to be described later, corresponding to the position where the runner portion 7 is formed. Since the runner portion 7 according to the present embodiment is formed radially, the insertion holes 9 are formed at a plurality of positions corresponding to the shape of the runner portion 7.
[0044]
Each of the insertion holes 9 is a non-through hole having an opening formed on the other surface of the base plate 2, and a female screw 12 is formed at an end of the opening so as to screw a retaining ring 11 described later. ing. In addition, a detent groove 13 for preventing (rotating) the shaft body 8 from rotating around the axis is formed on the inner peripheral surface of each insertion hole 9 from the opening end in the center axis direction. It is formed toward the back.
[0045]
In each of the insertion holes 9 of the base plate 2 formed as described above, a shaft body 8 having one end (one end) protruding and retracting from the other surface to the one template 4a side is connected to the one template 4a. It is inserted so as to be movable in the axial direction corresponding to the separating direction. The base plate 2 is provided with a coil spring 10 as urging means for urging each shaft body 8 toward one template 4a.
[0046]
The shaft body 8 is a stepped rod having a substantially circular cross section having a large-diameter portion 14 for retaining at the other end. A part of the outer peripheral surface of the large diameter portion 14 is provided with a pin 15 that is inserted into the detent groove 13. The pin 15 is inserted into the detent groove 13, and is drilled in the base plate 2. The large-diameter portion 14 is positioned on the inner side of the insertion hole 9 so as to be movable in the axial direction.
[0047]
The outer diameter of the shaft body 8 on the small diameter side is set to be larger than the groove width of a runner groove 22 described later, as compared with the large diameter part 14, and one mold plate 4 a is formed on the other surface of the base plate 2. When approaching or coming into close contact with, a part of one end surface of the shaft body 8 is pushed by one of the template plates 4a against the bias of the coil spring 10 and buried in the base plate 2. That is, since the outer diameter of the small diameter portion of the shaft body 8 is set to be larger than the width of the runner groove 22, the shaft body 8 has a portion of one end surface without one end entering the runner groove 22. Is pushed by one surface of one mold plate 4 a and pushed into the base plate 2.
[0048]
A retaining ring 11 having a male screw 17 formed on the outer peripheral surface is screwed into one end opening of the insertion hole 9 of the base plate 2, and the shaft body is inserted into the inner hole of the retaining ring 11. 8 is inserted at one end. Thus, when the shaft body 8 moves to the opening side of the insertion hole 9, the large diameter portion 14 of the shaft body 8 and the retaining ring 11 interfere with each other, and the shaft body 8 It is prevented (fall-out) from dropping to the 4a side. In other words, the shaft body 8 is inserted into the insertion hole 9 such that one end thereof protrudes and retracts from the other surface of the base plate 2 by moving in the axial direction in a state where the shaft body 8 is prevented from rotating and retaining. ing.
[0049]
Further, a holding groove 16 for holding a runner material R formed in the runner portion 7 is formed at one end of the shaft body 8 that protrudes and retracts from the other surface of the base plate 2. The holding groove 16 is shaped so that resin from the runner part 7 can flow in a state where one end of the shaft body 8 is buried in the base plate 2.
[0050]
The shape of the holding groove 16 is set so as to prohibit the resin that has flowed in and solidified from moving in the axial direction of the shaft body 8 (the direction in which one of the mold plates 4a described later is separated), and has been solidified. The resin is shaped so as to be detachable from the opening side of the holding groove 16.
[0051]
More specifically, the holding groove 16 is formed so as to form an open portion 18 on one end surface of the shaft body 8 and extend in the axial direction. The holding groove 16 is dug deeper toward the axis than the opening 18 at a position on the other end side of the opening 18 (the other end of the holding groove 16 in the present embodiment). A locking recess 19 having a large depth is formed.
[0052]
As a result, even if the resin attempts to move to one end of the shaft body 8, the resin solidified in the deeply dug portion cannot pass through the opening 18, and is not allowed to pass through the opening 18 (in the direction of one of the mold plates 4 a described later). (Moving in the direction of separation) can be prohibited.
[0053]
The holding groove 16 has an opening-side groove width set to be equal to or greater than the groove width at the groove bottom. Accordingly, when one end of the shaft body 8 is buried in the base plate 2, the solidified resin moves to the opening side of the holding groove 16 because the shaft 8 faces the inner peripheral surface of the retaining ring 11. Will not. On the other hand, when one end of the shaft body 8 protrudes from the base plate 2, the resin solidified in the holding groove 16 can be easily released to the opening side of the holding groove 16.
[0054]
Further, one end of a guide rod 20 for guiding the movement of the pair of template plates 4a and 4b is fixed to the other surface of the base plate 2, and the guide rod 20 has an axis centered on the base plate 2. It is provided so as to be substantially perpendicular to the other surface.
[0055]
The guide rod 20 is fixed to a support plate 21 whose other end is substantially parallel to the other surface of the base plate 2, and does not swing with the movement of the template plates 4a, 4b. It has become. The length of the guide rod 20 is set in consideration of the distance between the pair of template plates 4a and 4b from the base plate 2 and the distance between the one template plate 4a and the other template plate 4b.
[0056]
One of the mold plates 4a of the pair of mold plates 4a and 4b has a runner groove 22 for forming the runner portion 7 formed on one surface, and a mold for forming the molding space 3 (in the present embodiment). Has a cavity 23) formed on the other surface.
[0057]
The runner groove 22 is formed radially starting from a position corresponding to the first sprue portion 6 of the opposing base plate 2, and the runner portion 7 is formed radially as described above. Further, a second sprue portion 24 that connects the molding space 3 (inside the cavity 23) and the runner portion 7 (the runner groove 22) is formed in the one mold plate 4a.
[0058]
The second sprue portion 24 is formed so as to substantially coincide with the direction in which the first sprue portion 6 is formed. A gate portion 25 having a reduced diameter is formed at a connection portion with the molding space 3, and is connected to the runner portion 7. The portion has a diameter larger than that of the gate portion 25 and is formed in a substantially conical shape.
[0059]
The other mold plate 4b has a mold (core 26 in the present embodiment) for forming the molding space 3 formed on one surface.
[0060]
Each of the pair of template plates 4a and 4b is provided with a guide hole 27 guided by the guide bar 20, and the other template plate 4b is provided along one of the template plates 4a along the guide bar 20. (The other surface) so that one template 4a (a pair of template 4a, 4b) can be separated from the other surface of the base plate 2.
[0061]
As shown in FIG. 2 (a), the injection mold having the above-described structure is configured such that the molten resin injected by the injection molding machine is filled with the injection flow path 1 (nozzle connection section 5, first sprue section 6), runner section. 7, flows into the molding space 3 via the second sprue portion 24 and fills them.
[0062]
In this state, as shown in FIG. 3, the shaft body 8 inserted into the base plate 2 is pushed by the one mold plate 4a and is completely buried in the base plate 2, and the runner portion 7 is formed. The molten resin therein flows into the holding groove 16 through the opening 18 on one end surface, and the inside of the holding groove 16 is also filled with the molten resin.
[0063]
Then, when the resin in the molding space 3 is solidified to form the molded product P, the resin R in the first sprue portion 6, the runner portion 7, the second sprue portion 24, and the holding groove 16 (hereinafter referred to as these The connected resin is also called a runner material), and the runner material R in each of these portions is in a connected state.
[0064]
In this state, the runner material R in the holding groove 16 connected to the runner material R in the runner portion 7 is such that the runner material R in the locking recess 19 is closer to the axis of the shaft 8 than the open portion 18. Since it has flowed and solidified, it is solidified in a state where it cannot move in the axial direction in the holding groove 16. When the pair of mold plates 4a and 4b are separated from the base plate 2 in order to separate the molded product P and the runner material R, the runner connected to the molded product P in the molding space 3 as shown in FIG. The shaft body 8 is pulled by the runner material R in the holding groove 16 so that the material R tends to separate from the base plate 2 at the same time, and one end of the shaft body 8 protrudes from the other surface of the base plate 2 toward the template. It becomes. For example, even if the resin slightly flows between the inner peripheral surface of the retaining ring 11 and the outer peripheral surface of the shaft body 8 and the shaft body 8 is hard to move, the shaft body 8 is Since the urging force is applied, the urging force acts on the urging member so that the urging member can move in the axial direction.
[0065]
When the large-diameter portion 14 of the shaft body 8 and the retaining ring 11 interfere with each other to prevent the shaft body 8 from coming off, when the pair of mold plates 4a and 4b further separate from the base plate 2, the molding is performed. The tensile force concentrates on the connection portion between the product P and the runner material R (the portion corresponding to the gate portion 25), and finally the vicinity of the inside of the gate portion 25 is cut off, and as shown in FIG. And the runner material R are separated. In this state, the runner R is separated from the one template 4a, and the runner R is held by the shaft body 8 (holding groove 16). Therefore, the second sprue portion 24 is in a free end. It becomes.
[0066]
Then, as shown in FIG. 2 (d), the other mold plate 4b is separated from the one mold plate 4a, and the molded product P formed between the pair of mold plates 4a, 4b can be taken out. .
[0067]
In this state, the runner material R in the portion formed in the second sprue portion 24 is a free end, and one end of the shaft body 8 is discharged from the base plate 2 so that all of the holding grooves 16 are discharged. When the runner material R is moved from the axis of the shaft body 8 toward the opening of the holding groove 16 as shown in FIG. 4, the runner material R in the holding groove 16 is held. The runner R is removed from the groove 16 and is removed.
[0068]
As described above, according to the injection molding die according to the present embodiment, the base plate 2 protrudes and retracts from the base plate 2 to the pair of template plates 4a, 4b (one template plate 4a) in accordance with the formation position of the runner portion 7. A possible shaft body 8 is inserted into the base plate 2, and a holding groove 16 for holding a runner R is formed at one end of the shaft body 8 that protrudes and retracts from the base plate 2. When separating the runner material R, the runner material R can be securely held so that a tensile force acts on the connection between the molded product P and the runner material R.
[0069]
On the other hand, since the shape of the holding groove 16 is set so that the solidified resin (runner material R) can be released to the opening side of the holding groove 16, the runner material R and the molded product P are separated from the runner material R. When removing the resin, the resin whose movement in the axial direction (moving direction of the template) of the shaft body 8 is prohibited (restricted) can be easily separated from the opening of the holding groove 16 exposed from the base plate 2. it can.
[0070]
Therefore, a runner stripper plate for removing the runner material R, a drive source and a drive mechanism for operating the runner stripper plate, and the like as in the conventional injection molding die are not required, and the configuration can be simplified. Further, the operation time of the runner stripper plate, which has been required so far, can be reduced, and the molding efficiency can be improved. In addition, since the runner stripper plate is not used when removing the runner material R, no impact noise, which has conventionally been generated by the operation of the runner stripper plate, is generated, and it is possible to contribute to the working environment.
[0071]
Further, the shaft body 8 is provided so as to be able to protrude and retract from the base plate 2 to the mold plate 4a side, and the shaft body 8 is forcibly buried by pressing the mold plate 4a. There is no obstacle in the flow of the resin inside 7, and the flow of the resin can be made smooth.
[0072]
Further, since the coil spring 10 as an urging means for urging the shaft body 8 toward the one mold plate 4a is provided in the base plate 2, even if the shaft body 8 becomes difficult to move due to resin inflow or the like, the coil spring can be used. The movement of the shaft body 8 can be assisted by the ten spring force (biasing force).
[0073]
Furthermore, in order to prevent the shaft body 8 from rotating around the axis, the shaft body 8 is detented and the holding grooves 16 of the plurality of shaft bodies 8 are arranged in the same direction. Is formed in a complicated shape, the runner material R formed in the runner portion 7 can be securely and sufficiently held, while the runner material R is easily removed when the runner material R is removed. Can be removed.
[0074]
In addition, the injection mold of the present invention is not limited to the above embodiment, and it is needless to say that various changes can be made without departing from the gist of the present invention.
[0075]
In the present embodiment, the shaft 8 is formed in a circular cross section, and the pin 15 for preventing rotation is protruded from the large diameter portion 14. However, the present invention is not limited to this. May be formed in a polygonal shape, and the shape of the inner hole of the retaining ring 11 may be set to a shape corresponding to the cross-sectional shape of the small diameter portion of the shaft body 8. Even in this case, the rotation of the shaft body 8 can be prevented. Also in this case, the shaft body 8 is, of course, prevented from falling off to the one template 4a side.
[0076]
In the present embodiment, since the runner portions 7 are formed radially in a plan view, the shaft bodies 8 are provided at a plurality of positions corresponding to the formation positions of the runner parts 7. However, the present invention is not limited to this. May be appropriately provided in a quantity corresponding to the shape, the length, and the like of the runner portion 7. When only one shaft 8 is provided, the solidified resin is released from the inside of the holding groove 16 without being affected by the direction in which the holding grooves 16 of the other shafts 8 are formed. No need.
[0077]
In the present embodiment, the coil spring 10 is provided in the base plate 2 as urging means for urging the shaft body 8 in the axial direction. However, the present invention is not limited to this. A rubber body having a possible elasticity may be provided inside.
[0078]
In the present embodiment, the urging means is provided. However, the present invention is not limited to this. The urging means may be provided when it is necessary to assist the operation of the shaft 8. In this case, the resin solidified in the holding groove 16 reliably holds the runner material R pulled by the movement of the template, and maintains the engagement with the holding groove 16 against the pulling force due to the movement of the template. What is necessary is just to set the shape of the holding groove 16 so that it may become the shape which can be performed.
[0079]
In the present embodiment, the diameter of the small diameter portion of the shaft body 8 is set to be larger than the groove width of the runner groove 22, and one end surface of the shaft body 8 is pressed by the one mold plate 4 a, so that the shaft body 8 is Although it is made to be completely buried in the plate 2, the present invention is not limited to this. For example, the diameter of the small diameter portion of the shaft body 8 is made smaller than the groove width of the runner groove 22 to reduce the diameter of the shaft body 8. The portion may be made to protrude into the runner groove 22, and the shaft body 8 may be pushed into the base plate 8 by the injection pressure of the resin. In order to push the shaft body 8 into the base plate 8 by the injection pressure, the length of the shaft body 8 protruding from the other surface of the base plate 2 toward the template 4a is shorter than the groove depth of the runner groove 22. Preferably, a gap is formed between the groove bottom surface of the runner groove 22 and one end surface of the shaft body 8 so that the resin can flow. Further, when the resin flows into the runner portion 7, the inside of the insertion hole 9 is sucked, and the shaft body 8 is forcibly buried in the base plate 2 (the insertion hole 9) by the suction force. Good.
[0080]
In the present embodiment, by forming a locking recess 19 that is dug down toward the axis of the shaft body 8 at the other end of the holding groove 16, the resin solidified in the holding groove 16 is formed in the runner portion 7. However, the shape of the holding groove 16 is not limited to this. For example, the holding groove 16 may be dug down from the open portion 18 toward the other end toward the axial center. Is formed so that the bottom surface is inclined, the groove depth of the holding groove 16 is made constant, and a portion where the groove width at the other end side of the opening 18 is wider than the groove width of the opening 18 is formed. The groove width on the other end side from the open portion 18 is wider than the groove width on the open portion 18, and the groove depth on the other end side from the open portion 18 is set deeper than the open portion 18. It can be shaped and the like. However, it is needless to say that the holding groove 16 is formed so that the resin solidified in the holding groove 16 can be released to the opening side.
[0081]
In the present embodiment, the retaining ring 11 is screwed onto the base plate 2 in order to prevent the shaft 8 from coming off. However, the present invention is not limited to this. For example, the insertion hole 9 may be provided on the other surface side. The opening may be formed with a small diameter, and the opening on one surface may be formed with a stepped hole that has a large diameter and penetrates through the base plate 2. That is, a small diameter portion may be formed instead of the retaining ring 11 of the present embodiment. In this case, the shaft 8 may be inserted through a large-diameter opening to close the opening.
[0082]
In the present embodiment, one surface of the base plate 2 is configured to be directly connectable to the nozzle of the injection molding machine. However, the present invention is not limited to this. A mounting plate for mounting on a metal mold may be connected.
[0083]
In the present embodiment, the shaft body 8 is directly inserted into the base plate 2. However, the present invention is not limited to this. For example, a later-described runner holder (runner holder according to the second embodiment) may be attached. Of course.
[0084]
Next, a second embodiment of the present invention will be described with reference to the drawings.
[0085]
FIG. 5 is a cross-sectional view of the runner holder according to the present embodiment. Such a runner holder is capable of retrofitting the function of holding the runner R (shaft 8) to an injection mold that does not have the function of holding the runner R (shaft 8) described in the first embodiment. It was made. Since the injection molding die to which the runner holder is attached is substantially the same as the injection molding die of the first embodiment, the base plate and the pair of mold plates have the same reference numerals as those of the first embodiment, The description is omitted using the same name.
[0086]
The runner holder according to the present embodiment includes a cylindrical body 30 having a bottomed cylindrical shape, and a shaft body 31 that is axially aligned with the cylindrical body 30 and is inserted so as to be movable in the axial direction. Have. Further, the runner holder has a coil spring 32 as urging means for urging the shaft 31 toward the one end opening side of the cylindrical body 30.
[0087]
The cylindrical body 30 has a cylindrical portion 33 having a cylindrical shape, and has a length in the axial direction corresponding to the thickness of the base plate 2. The tubular portion 33 is provided with a stop groove 34 penetrating so as to extend in the axial direction. Further, the tubular body 30 has a flange 35 formed on the outer periphery of the bottom. The flange 35 has a first concave portion 37 into which a part of a stop member 36 for preventing the cylindrical body 30 from coming off and preventing the rotation of the cylindrical body 30 with respect to the base plate 2 is an end of an end surface (the bottom surface of the cylindrical body 30). It is formed on the edge. The stop member 36 is a plate having a rectangular shape in a plan view, and has a hole 39 through which the screw member 38 is inserted.
[0088]
The shaft body 31 is a cylindrical body, and a locking pin 40 is driven into a part of the outer peripheral surface. The shaft body 31 is inserted into the cylindrical body 30 in a state where the locking pin 40 is present in the stop groove 34 of the cylindrical body 30, and one end side can be protruded and retracted from the open end of the cylindrical body 30. The rotation of the shaft body 31 and the removal of the shaft body 31 are prevented by interposing the locking pin 40 in the locking groove 34. The outer diameter of the shaft body 31 is set to be larger than the groove width of the runner groove 22 of the one template 4a.
[0089]
The shaft 31 has a holding groove 42 in which an open portion 41 is formed on one end surface at one end protruding and retracting from the open end of the cylindrical body 30 to the outside. The holding groove 42 is formed in the same configuration as the holding groove 16 of the first embodiment. When the runner holder is attached to the injection molding die (base plate 2) and the molten resin is poured. The shape is set so that the resin from the runner portion 7 of the injection mold can flow in.
[0090]
When the resin is attached to the injection molding die, the holding groove 42 moves the resin that has flowed in from the runner portion 7 and solidified in the axial direction of the shaft body 31 (the direction in which one of the mold plates 4a described later is separated). The shape is set so as to prohibit the solidification of the resin, and the solidified resin is shaped so as to be detachable to the opening side of the holding groove 42. That is, the holding groove 42 is formed so as to form the open portion 41 on one end surface of the shaft body 31 and extend in the axial direction.
[0091]
The holding groove 42 is dug deeper toward the axis than the opening 41 at a position on the other end side of the opening 41 (the other end of the holding groove 42 in the present embodiment). A locking recess 43 having a large depth is formed.
[0092]
As a result, even if the resin attempts to move to one end side of the shaft body 31, the resin solidified in the locking concave portion 43 cannot pass through the open portion 41, and the resin hardens in the axial direction (separation of the one template 4 a). Direction).
[0093]
The holding groove 42 has an opening-side groove width set to be equal to or larger than the groove width at the groove bottom. Accordingly, when one end of the shaft body 31 is buried in the base plate 2, the solidified resin moves to the opening side of the holding groove 42 because the one end of the shaft body 31 faces the inner peripheral surface of the cylindrical body 30. Will not. On the other hand, when one end of the shaft body 31 protrudes from the base plate 2, the resin solidified in the holding groove 42 can be easily released to the opening side of the holding groove 42.
[0094]
Further, a spring interior hole 44 in which the coil spring 32 is housed is formed in the other end surface of the shaft body 31 in the axial direction in a non-penetrating state.
[0095]
The coil spring 32 is housed in a spring interior hole 44 of the tubular body 30, and has one end abutting on the bottom surface of the spring interior hole 44 and the other end abutting on the inner surface of the bottom of the tubular body 30. The shaft 31 is urged toward the opening end of the cylindrical body 30.
[0096]
In order to attach the runner holder having the above-described configuration to the injection molding die, first, the cylindrical body 30 is fitted into the other surface of the base plate 2 corresponding to the molding position of the runner part 7. Hole 45 is drilled. The interior hole 45 has a shape corresponding to the outer shape of the tubular body 30, and a flange fitting hole into which the flange 35 of the tubular body 30 is fitted on one surface side of the base plate 2. A stepped hole having 46.
[0097]
Further, a second recess 47 is formed adjacent to the flange fitting hole 46 for fitting a part of the stop member 36, and the stop member 36 is fitted in the second recess 47 in a state where the stop member 36 is fitted in the second recess 47. A screw hole 48 for screwing the screw member 38 into which the hole 39 is inserted is formed.
[0098]
Then, the tubular body 30 in which the shaft body 31 and the coil spring 32 are assembled is fitted and buried in the base plate 2 so that the open end of the tubular body 30 matches the other surface of the base plate 2. The reason why the opening end of the tubular body 30 is aligned with the other surface of the base plate 2 is that when the opening end of the tubular body 30 projects from the other surface of the base plate 2, the molten resin This surrounds the opening end, which is a hindrance when removing the runner material R.
[0099]
Then, the stop member 36 is fitted into the concave portion formed by integrally forming the first concave portion 37 and the second concave portion 47 of the cylindrical body 30, and the screw member 38 is screwed into the screw hole 48 through the hole 39. I do. In this state, the cylindrical body 30 is in a state in which the base plate 2 is prevented from rotating and coming off.
[0100]
In this state, similarly to the shaft body 31 of the first embodiment, one end of the shaft body 31 of the present embodiment can be protruded and retracted from the other surface of the base plate 2 toward the one template 4a. State. Further, since the outer diameter of the shaft body 31 is set to be larger than the groove width of the runner groove 22, the shaft body 31 is brought close or close to one of the mold plates 4a with respect to the other surface of the base plate 2. It is pushed into the tubular body 30 and becomes buried.
[0101]
Therefore, since the shaft 31 of the present embodiment has the same holding groove 16 as the shaft 8 of the first embodiment, the runner holding mold is not provided with the function of holding the runner material R. By attaching the tool, the same operation and effect as those of the first embodiment can be obtained, and the runner material R is easily removed from the injection mold that does not have the function of holding the runner material R. It is possible to easily add a function for improving the work efficiency, such as the ability to perform the task.
[0102]
In addition, the injection mold of the present invention is not limited to the above embodiment, and it is needless to say that various changes can be made without departing from the gist of the present invention.
[0103]
In the present embodiment, while the cylindrical portion 33 of the cylindrical body 30 is formed in a cylindrical shape, and the shaft body 31 is formed in a cylindrical shape, the present invention is not limited to this. The inner hole shape of the cylindrical body 30 may also correspond to the cross-sectional shape of the shaft body 31. By doing so, the shaft body 31 is in a state where it is prevented from rotating, but since it is in a state where it is not stopped, it is needless to say that a separate stopper is provided.
[0104]
In the present embodiment, the coil spring 32 for urging the shaft body 31 is provided. However, the present invention is not limited to this, and the coil spring 32 does not need to be provided. In this case, the resin that solidifies in the holding groove 42 reliably holds the runner material R pulled by the movement of the template, and engages with the holding groove 42 against the pulling force due to the movement of the template 4a, 4b. The shape of the holding groove 42 may be set so that the shape of the holding groove 42 can be maintained.
[0105]
In the present embodiment, a plurality of runner holders are attached to the base plate 2. However, the present invention is not limited to this, and the runner holders are appropriately provided in a number corresponding to the shape and length of the runner part 7. Just fine. When the runner holder is provided so as to hold the runner material R at one place, the arrangement of the other shaft body 31 with the holding portion may cause another solid body 31 to separate the solidified resin from the inside of the holding groove 42. Is not affected by the direction in which the holding groove 42 is formed, so that the rotation of the shaft body 31 is not particularly required.
[0106]
In the present embodiment, the hole for spring interior 40 is formed in the other end surface of the shaft body 31 and the coil spring 32 is installed in the hole for spring interior 40. However, the present invention is not limited to this. Similarly to the above, the coil spring 32 may be internally provided between the other end surface of the shaft body 31 and the bottom surface of the interior hole 45.
[0107]
Further, the urging means for urging the shaft body 31 toward the one end opening side of the cylindrical body 30 is not limited to the coil spring 32, but a rubber body having an elastic force capable of urging the shaft body 31 or the like. It may be.
[0108]
Further, in the present embodiment, the outer diameter of the shaft body 31 is set to be larger than the groove width of the runner groove 22, and one end surface of the shaft body 31 is pressed by the one mold plate 4a, so that the shaft body 31 is However, the present invention is not limited to this. For example, the outer diameter of the shaft body 31 is made smaller than the groove width of the runner groove 22 so that one end of the shaft body 31 is formed in the runner groove. 22. Then, the runner holder may be attached to the base plate 2, and the shaft 31 may be pushed into the cylindrical body 30 (base plate 2) by the injection pressure when the resin is injected into the flow path. In order to push the shaft body 31 into the base plate 2 by the injection pressure, the length of the shaft body 31 protruding from the other surface of the base plate 2 toward the template 4a is shorter than the groove depth of the runner groove 22. Preferably, a gap is formed between the groove bottom surface of the runner groove 22 and one end surface of the shaft body 31 so that the resin can flow.
[0109]
【The invention's effect】
As described above, according to the injection molding die of the present invention, one end side can be protruded and retracted from the close contact surface of the base plate to the template side at a position corresponding to the formation position of the runner portion on the base plate. The shaft body is inserted so that it can move in the direction of separation of the template, and the shaft body is prevented from falling off to the close contact surface side of the base plate, and one end side when the resin flows in the runner part. A holding groove having an opening on one end surface of the shaft body is formed so as to be buried in the plate, and has an opening through which resin from the runner part can flow in a portion protruding and retracting from the close contact surface. The holding groove is formed so as to prohibit the resin that has flowed in and solidified from moving in the separating direction of the template, and has such a shape that the solidified resin can be detached to the opening side of the holding groove. Therefore, when separating the molded product from the runner material, The runner member while capable of holding, in removing the runners material separated from the molded article, the runner material without using a runner stripper plate can be easily removed to.
[0110]
Further, according to the runner holder of the present invention, a tubular body buried in the base plate with one end opening corresponding to the close contact surface of the base plate and one end side of the tubular body corresponding to the formation position of the runner portion. It is inserted movably along the axis of the cylindrical body so that it can emerge from the opening to the outside, and so that one end side is buried in the cylindrical body when the resin flows in the runner part. In addition, a holding groove having an opening on one end surface of the shaft body is formed at a position where the resin from the runner portion can flow in at a position where the holding groove protrudes from the one end opening of the cylindrical body. Since the solidified resin is set so as to prohibit the solidified resin from moving in the separating direction of the one mold plate, and the solidified resin is set to be detachable to the opening side of the holding groove, the runner material is removed. Injection molds without holding function If the runner holder is attached, the runner material can be reliably held when the molded product is separated from the runner material, while the runner stripper plate is removed when the runner material separated from the molded product is removed. The runner material can be easily removed without using it.
[Brief description of the drawings]
FIG. 1 shows a cross-sectional view of an injection mold according to a first embodiment of the present invention.
FIGS. 2A and 2B are explanatory views of the operation of the injection molding die according to the embodiment, wherein FIG. 2A shows a state in which a molten resin is injected, and FIG. (C) shows a state in which the molded article and the runner material are separated from each other, and (d) shows a state in which the runner material can be taken out.
FIG. 3 is a partial cross-sectional view showing a flow state of a molten resin near a shaft body and a runner portion according to the embodiment.
FIG. 4 is a partial explanatory view of a state in which the runner material is taken out of the injection mold according to the embodiment.
FIG. 5 shows a sectional view of a runner holder according to a second embodiment of the present invention.
FIG. 6 is a schematic explanatory view of a conventional injection mold.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Injection channel, 2 ... Base plate, 3 ... Molding space, 4a, 4b ... Mold plate, 5 ... Reservoir part, 6 First sprue part, 7 ... Runner part, 8 ... Shaft, 9 ... Insertion hole, DESCRIPTION OF SYMBOLS 10 ... Coil spring (biasing means), 11 ... Retaining ring body, 12 ... Female screw, 13 ... Detent groove, 14 ... Large diameter part, 15 pin, 16 ... Holding groove, 17 ... Male screw, 18 ... Open part, 19: locking recess, 20: guide rod, 21: support plate, 22: runner groove, 23: cavity, 24: second sprue, 25: gate, 26: core, 27: guide hole, 30: cylinder Shape: 31: Shaft, 32: Coil spring, 33: Cylindrical part, 34: Stop groove, 35: Flange, 36: Stop member, 37: First concave portion, 38: Screw member, 39: Hole, 40: Spring Interior hole, 40: locking pin, 41: open portion, 42: holding groove, 43: locking recess, 44: spring interior hole, 45: interior hole, 46 ... Flange fitting hole, 47 ... Second recess, 48 ... Screw hole, P ... Molded product, R ... Runner material

Claims (6)

For the base plate having the first sprue portion into which the resin is injected, of the pair of template plates forming the molding space by clamping, one of the template plates having the second sprue portion communicating with the molding space is used. The close contact makes it possible to form a runner portion that connects the first sprue portion and the second sprue portion between the close contact surfaces of one template plate and the base plate, and separates the template plate from the base plate. By doing so, a molded product molded in the molding space, and a runner material present in the runner portion is an injection molding die configured to be separated, the base plate, the runner portion of the At a position corresponding to the forming position, a shaft body is inserted so as to be movable in a separating direction of the template, so that one end side can be protruded and retracted from the close contact surface of the base plate to the template side. The plate is prevented from falling off to the close contact side, and One end side of the shaft body is configured such that one end side is buried in the base plate when the fat flows, and a resin part from the runner part can flow into and out of the close contact surface. Is formed, the holding groove is shaped so as to prohibit the resin that has flowed in and solidified from moving in the separating direction of one of the mold plates, and the solidified resin has the shape of the holding groove. An injection molding die having a shape set to be detachable from an opening side. 2. The injection molding die according to claim 1, wherein a biasing means for biasing the shaft body toward the template is provided in the base plate. The injection molding die according to claim 1, wherein a plurality of the shafts are provided, and each of the shafts is restricted from rotating around an axis with each holding groove facing in the same direction. For the base plate having the first sprue portion into which the resin is injected, of the pair of template plates forming the molding space by clamping, one of the template plates having the second sprue portion communicating with the molding space is used. By being brought into close contact with each other, a runner portion that connects the first sprue portion and the second sprue portion is formed between the close contact surfaces of one mold plate and the base plate. A runner holder for holding the runner material when separating the mold plate from the base plate so as to separate the molded product in the molding space from the runner material present in the runner portion, the runner portion comprising: The cylindrical body is buried in the base plate with one end opening corresponding to the close contact surface of the base plate, and the cylindrical body is formed such that one end side can protrude and retract from the one end opening of the cylindrical body. And a shaft body movably interpolated. Is configured so that one end side of the cylindrical body is prevented from falling off at the one end opening side, and one end side is buried in the cylindrical body when the resin flows in the runner portion. A holding groove having an opening at one end surface of the shaft body is formed at a portion where the resin from the opening protrudes and is allowed to flow in the resin from the runner portion. A runner holder, wherein the shape is set so as to prohibit movement in the direction, and the solidified resin is shaped so as to be detachable from the opening side of the holding groove. 5. The runner holder according to claim 4, wherein a biasing means for biasing the shaft body toward the one end side is provided inside the cylinder main body. The runner holder according to claim 4, wherein the shaft body is restricted from rotating around an axis.