JP2008213468A - Injection mold and partial compression molding method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mold which does not require a complicated driving source such as a hydraulic mechanism, which prevents the formation of a sink mark appearing on the appearance surface of a thick-walled section of a molded article, which does not cause unevenness in transfer or unevenness in gloss, and which can mold a rib or a boss with high dimensional precision, and to provide its molding method. <P>SOLUTION: Until the initial stage of the start of filling, a partial compressing pin is precedently pressurized and advanced up to a cavity surface by an urging member. Resin pressure during the filling makes the partial compressing pin recede, and thus, a compression boss is formed. After the completion of the filling, the compression boss is compressed by the partial compressing pin. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an injection mold used for molding a resin molded product, and a partial compression molding method thereof.

  In the conventional partial compression molding die, as described in Patent Document 1, the ejector pin is moved backward so as to form a recess by a compression allowance from the die surface forming the inner surface of the molded product, In this state, there is a mechanism in which the concave portion and the cavity portion are filled with resin and then compressed with an ejector pin. Also, as described in Patent Document 2, there is a type in which the tip of the boss is compressed with an ejector pin, and a type in which the periphery of the boss is compressed with a sleeve pin. It is also known to compress the inner hole portion of the boss portion having a hole as described in Patent Document 3.

  Hereinafter, conventional partial compression molding will be described with reference to FIGS.

  In the injection compression molding mold shown in FIG. 7, the cavity 1 is formed by the mold 6 and the core mold 7, and the tip of the ejector pin 17 is a compression boss from the mold surface forming the inner surface of the cavity 1. It is held in a state of being retracted so as to form a recess by a certain compression boss 4 minutes. (Hereinafter, the compression boss is referred to as a compression boss.) Further, a compression mechanism comprising a plurality of hydraulic chambers 18 and hydraulic cylinders 19 driven by hydraulic pressure among them is provided in the movable mounting plate 10. These hydraulic cylinders 19 are arranged on the rear surface of the ejector plate 9 connected to the ejector pins 17. In order to mold a molded product using the mold having such a configuration, filling of the molten resin is started in a state where the ejector pin 17 is retracted from the core surface by the compression boss 4, and the space between the cavity 1 and the compression boss 4 is started. Fill the part. When the filling is completed, the compression mechanism is operated, and the plurality of hydraulic cylinders 19 press the ejector plate 9 and thus the tip of the ejector pin 17 in the direction of the cavity 1 (the right direction in the figure). Compress. By this compression action, pressure is transmitted almost uniformly to every corner of the molding die, and sink marks in the rib portion can be eliminated. For compression of the boss, the tip of the boss 20 is compressed by a sleeve pin 21 that can be slid by the hydraulic cylinder 19 as shown in FIG. 8, or the inner diameter that forms the recess of the boss 20 as shown in FIG. Some pins 22 are compressed by the hydraulic cylinder 19 to prevent the back of the boss from sinking.

As described above, the ejector pin is set in the position retracted by the compression allowance before filling with the resin, and the compression boss is formed at the time of filling with the resin. Is possible.
JP-A-5-228970 JP-A-11-198198 JP 2002-283422 A

  However, in the conventional method, since the resin flows into the compression boss side when the resin is filled, the leading end portion of the resin that flows at the cavity surface portion is undulated, and flow unevenness is likely to occur. In addition, the resin flow into the compression boss reduces the resin pressure at the opposite surface portion of the cavity where the compression boss is formed, and the opposite surface portion (back surface) of the cavity where the compression boss is formed and its resin. In some cases, the downstream portion of the flow of the resin is not filled with resin, and appearance defects such as uneven transfer and uneven gloss may occur. In addition, since there is a pressure difference in the cavity after resin filling, when the compression boss is compressed with an ejector pin, there is a difference in the compression pressure depending on the position of the ejector pin, and a sufficient compression pressure may be applied to the required location. difficult. Furthermore, the compression operation requires the use of a hydraulic cylinder, which complicates the mold structure and increases the cost.

  The present invention has been made in view of the above-described problems, and prevents the occurrence of sink marks on the back of ribs and bosses of a molded product, and provides an injection mold for providing a molded product having an excellent appearance, and the molding thereof. It aims to provide a method.

  In order to solve the above-described problems and achieve the object, an injection mold according to the present invention includes a fixed mold, a movable mold that forms a cavity between the fixed mold, and the movable mold. A partial compression pin penetrating the side mold and having a front end surface forming part of the cavity surface; and the front end surface of the partial compression pin is disposed on the partial compression pin so as to recede from the cavity by resin pressure. An urging member and drive means for advancing the retracted front end surface of the partial compression pin toward the cavity again.

  Furthermore, the partial compression molding method of the present invention includes a step of forming a cavity surface by a fixed side mold, a movable side mold, and a front end face of the partial compression pin, a step of filling the cavity with a molten resin, The step of forming a compression boss by the front end surface of the partial compression pin retreating from the cavity surface by the pressure of the resin, and after the resin filling is completed, the partial compression pin is advanced toward the cavity to compress the compression. And a step of moving the resin in the boss into the cavity.

  In the present invention, since the compression boss is not formed at the start of resin filling, and the resin flows along the cavity, flow unevenness can be suppressed. In addition, since the compression boss is automatically formed by the resin pressure, a complicated drive source such as a hydraulic cylinder or an air cylinder is not required, and the mold structure can be simplified, thus lowering the mold cost. It can be suppressed. Furthermore, by partially compressing the compression boss, it is possible to prevent sink marks on the outer surface side of the ribs and bosses, and to prevent transfer unevenness and gloss unevenness caused by forming the compression boss.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a sectional view of an essential part of an injection mold according to the present invention. In FIG. 1, the fixed side mold 6 is fixed to the fixed side mounting plate 8, and the movable side mold 7 that forms a cavity with the fixed side mold 6 is movable via a spacer block (not shown). It is attached and held on the mounting plate 10. Further, a space portion 11 formed by a spacer block is provided between the movable side mold 7 and the movable side mounting plate 10. Here, a pair of ejector plates 9 that are pushed by an ejector rod 12 driven by an ejector cylinder (not shown) are provided so as to be movable in the cavity direction. A partial compression pin 3 is attached to the ejector plate 9 so as to penetrate therethrough. The partial compression pin 3 has a front end portion 3a, a flange portion 3b, and a rear end portion 3c. The urging member 13 is disposed on the outer periphery of the rear end portion 3c of the partial compression pin 3, and the urging member 13 presses and presses the flange portion 3b toward the cavity. The front end face 3d of the partial compression pin 3 is continuous with the cavity of the movable mold 7 of the cavity 1 until the resin filled in the cavity reaches a resin pressure equal to or higher than a predetermined pressure. Form part of the surface. The front end surface 3d of the partial compression pin 3 is configured to recede from the cavity surface when the resin pressure of the resin filled in the cavity becomes equal to or higher than a predetermined pressure. For the predetermined pressure, a small force is sufficient, and for example, it can be carried out if it is 1 Newton or more. Further, if the pressure is set so as to withstand a very strong pressure, it becomes difficult to form the compression boss 4 (FIG. 2). However, this is not limited as long as the pressure is such that the compression boss 4 is formed during resin filling. The cavity 1 is formed with a recess 2 that is a recess for forming a protrusion such as a rib on the molded product. The front end surface 3 d of the partial compression pin 3 is disposed so as to be positioned in the peripheral portion of the recess 2. On the opposite side surface portion (back surface) of the recess 2, sink marks or the like are likely to occur due to shrinkage accompanying cooling of the resin. It is effective to arrange the front end face of the partial compression pin 3 in the vicinity of the portion where the sink marks are likely to occur. In the present embodiment, the spring 13 is used as the urging member. However, the present invention is not limited to this, and an elastic member such as urethane rubber may be used. A large-diameter hole portion 14a corresponding to the flange portion 3b of the partial compression pin 3 is formed in the ejector plate 9, and the flange portion 3b of the partial compression pin 3 is accommodated in the large-diameter hole portion 14a. Further, the hole of the large-diameter hole portion 14a is made with play so that the flange portion 3b can be moved backward by the movable stroke a. As a result, the partial compression pin 3 can be retracted by the movable stroke a within the hole of the large-diameter hole, and has a structure movable within the range of the movable stroke a. Further, in the ejector plate 9, a medium diameter hole portion 14b having a smaller diameter than the large diameter hole portion and capable of accommodating the biasing member 13 is formed, and the spring 13 is accommodated therein.

  An ejector pin 17 is attached to the ejector plate 9 so as to penetrate therethrough. The ejector pin 17 has a front end portion 17a, a flange portion 17b, and a rear end portion 17c. The front end surface 17 d of the ejector pin 17 is disposed so as to form a part of the continuous surface of the cavity of the movable mold 7 of the cavity 1. A large-diameter hole portion 14c corresponding to the flange portion 17b of the ejector pin 17 is formed in the ejector plate 9, and the flange portion 17b of the ejector pin 17 is accommodated in the large-diameter hole portion 14c. Further, the hole of the large-diameter hole portion 14c is made with play so that the flange portion 17b can move backward by the movable stroke a. As a result, the ejector pin 17 can be retracted by the movable stroke a within the hole of the large-diameter hole portion 14c, and can move within the range of the movable stroke a.

  Next, a partial compression molding method for a molded product using the injection molding die configured as described above will be described with reference to FIGS.

  First, the fixed mold 6 and the movable mold 7 are clamped to form a cavity. Next, molten resin is injected and filled into the cavity from an injection nozzle (not shown). At that time, the partial compression pin 3 is pressed and pressed by the urging member 13 to form a part of the cavity surface of the movable mold of the cavity 1, so that the compression boss is not formed at the initial filling stage. Therefore, even in the region of the partial compression pin 3, since the resin flows along the cavity shape, flow unevenness does not occur. This state is shown in FIG.

  Thereafter, as the filling proceeds, the resin pressure in the cavity 1 rises, and when the resin pressure exceeds the pressing force of the biasing member 13, the partial compression pin 3 is automatically pushed back, and the partial compression pin 3 is moved by the compression stroke a. Retract and the compression boss 4 is formed. This state is shown in FIG. Before the compression boss 4 is formed, since the skin layer is already formed on the cavity surface 15 of the stationary mold due to cooling and solidification, the skin surface is not affected by the formation of the compression boss 4 and is not affected. Uniform transferability is ensured.

  After completion of filling of the molten resin and before opening the mold, and before the resin is still completely cooled and solidified, the ejector cylinder (not shown) is driven to advance the ejector rod 12 by a predetermined distance (right in the figure). Direction). The partial compression pin 3 moves forward (rightward in the figure) in conjunction with the ejector plate 9 and compresses the compression boss 4. This state is shown in FIG. In the present embodiment, the predetermined distance is set to the compression stroke a, the distance that the partial compression pin 3 retracts is advanced toward the cavity, and the compression boss 4 is not left in the molded product. The resin of the compression boss 4 is moved to the cavity. However, the present invention is not limited to this, and it is also possible to set a predetermined distance shorter than the movable stroke a and leave the compression boss 4 in the molded product. The movement of the resin in the compression boss 4 prevents the sinking of the opposite surface portion (back surface) of the cavity where the recess is formed. The hole of the large-diameter hole portion 14c in which the flange portion of the ejector pin is accommodated is formed with play so that the flange portion 17b can be retracted by the movable stroke a. Even if the ejector plate 9 advances by a distance of the movable stroke a, the ejector pin 17 does not advance toward the cavity, so that the shape of the molded product is not affected.

  FIG. 5 shows a state in the vicinity of the recess 2 after the compression boss 4 is formed and before the partial compression pin 3 is advanced. Due to the shrinkage caused by the cooling of the resin, sink marks 5 are generated in the cavity surface portion 15 of the stationary mold opposite to the cavity surface portion 16 of the movable mold in which the recess 2 is formed. By advancing the partial compression pin 3, the resin in the compression boss moves to the sink mark 5, and it becomes possible to compensate for the resin component lacking the sink mark 5. By arranging the front end face of the partial compression pin 3 in the vicinity of the recess 2, the resin in the compression boss easily moves to the sink mark 5, so that the effect is remarkable.

  FIG. 6 is a view showing an embodiment in which the concave portion 2 is a boss, and is a view showing a peripheral portion of the boss 20 formed in the cavity 1 in order to form the boss in a molded product formed by the cavity. is there. Due to the shrinkage caused by the cooling of the resin, sink marks 5 are generated on the cavity surface portion opposite to the cavity surface portion on which the boss 20 is formed. By advancing the partial compression pin 3, the resin in the compression boss 4 moves to the sink mark 5, and it becomes possible to compensate for the resin component lacking the sink mark 5. By arranging the front end face of the partial compression pin 3 in the vicinity of the boss portion, the resin in the compression boss easily moves to the sink marks 5, so that the effect is remarkable.

  After the resin is completely cooled and solidified, after the mold is opened, as shown in FIG. 4, the ejector rod 12 is further moved forward (to the right in the figure), and the ejector pin 17 interlocked with the ejector plate 9 is moved to the partial compression pin 3. Thus, the cavity 1 is released from the core mold 7.

  As described above, in the present invention, the compression boss is not formed at the start of resin filling, and the resin flows along the cavity, so that flow unevenness can be suppressed. In addition, since the compression boss is automatically formed by the resin pressure, a complicated drive source such as a hydraulic cylinder or an air cylinder is not required, and the mold structure can be simplified, thus lowering the mold cost. It can be suppressed. Furthermore, by partially compressing the compression boss, it is possible to prevent sink marks on the outer surface side of the ribs and bosses, and to prevent transfer unevenness and gloss unevenness caused by forming the compression boss.

It is principal part sectional drawing before the injection of the metal mold | die for injection molding in the Example of this invention. It is principal part sectional drawing after compression boss formation in the injection process of the same injection mold. It is principal part sectional drawing after the partial compression pin pressurization compression of the metal mold | die for injection molding. It is principal part sectional drawing at the time of taking out the molded product of the injection mold. It is a rib principal part sectional drawing of the rib shape-attached cavity of the injection mold. It is a boss vicinity essential part side view of the cavity with a boss shape of the injection mold. It is principal part sectional drawing before the compression molding of the conventional injection compression molding metal mold | die. It is principal part sectional drawing of the conventional cylindrical boss front-end | tip part compression molding metal mold | die. It is principal part sectional drawing of the conventional cylindrical boss recessed part compression molding die.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cavity 2 Recessed part 3 Partial compression pin 3a Partial compression pin Front end part 3b Partial compression pin Flange part 3c Partial compression pin Rear end part 3d Partial compression pin Front end surface 4 Compression boss 5 Sink 6 Fixed side mold 7 Movable side mold 8 Fixed Side mounting plate 9 Ejector plate 10 Movable side mounting plate 11 Space portion 12 Ejector rod 13 Energizing member 14a Large diameter hole portion 14b Medium diameter hole portion 14c Large diameter hole portion 15 Cavity surface portion of fixed side mold 16 Movable side die Cavity surface portion 17 Ejector pin 17a Ejector pin Front end portion 17b Ejector pin Flange portion 17c Ejector pin Rear end portion 17d Ejector pin Front end surface

Claims (6)

A fixed mold,
A movable mold that forms a cavity between the fixed mold and the fixed mold;
A partial compression pin that penetrates the movable mold and the front end surface forms part of the cavity surface;
An urging member disposed on the partial compression pin such that a front end surface of the partial compression pin is retracted from the cavity by resin pressure;
An injection mold comprising: drive means for advancing the retracted front end surface of the partial compression pin toward the cavity again.   The injection mold according to claim 1, further comprising an ejector pin and an ejector plate for projecting a molded product formed by the cavity.   The injection molding metal according to claim 2, wherein the partial compression pin has a flange portion, and the flange portion is movably accommodated in a large-diameter hole portion provided in the ejector plate. Type.   The injection mold according to claim 3, wherein the flange portion is urged by the urging member to press the front end of the partial compression pin toward the cavity.   2. The injection mold according to claim 1, wherein the biasing member is a spring or an elastic member. Forming a cavity surface by the front end face of the fixed side mold, the movable side mold and the partial compression pin;
Filling the cavity with molten resin;
Forming a compression boss by retreating the front end surface of the partial compression pin from the cavity surface by the pressure of the resin to be filled; and
After the resin filling is completed, the partial compression pin is advanced toward the cavity to move the resin in the compression boss into the cavity;
A partial compression molding method characterized by comprising:

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