JP3487929B2 - Injection molding of elastomer molded products - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing an elastomer molded article by injection molding a molten polymer material. Injection to prevent the surface from burning or dirt, and also to prevent burrs, deformation, gate failure, mold breakage, etc. due to high pressure filling, or to prevent sink marks due to polymer material shrinkage. It relates to a molding method. 2. Description of the Related Art Conventionally, when performing resin injection molding, there is a difference in cooling / solidification time of molten resin injected and filled in a cavity between a thick portion and a thin portion of a molded product. There has been a problem that a sink occurs in a meat portion. Recently, an injection molding method has been proposed which solves the problem of the sink (Japanese Patent Laid-Open No. 5-16177). This injection molding method
As shown in the mold 1 in FIG. 3, a void insertion pin 2 is erected at a position corresponding to a thick portion of a molded product, and after the resin is injected and filled into the cavity 3, the void insertion pin 2 is formed.
This is a method of forming a void in the resin by injecting air from the inside, and suppressing the shrinkage of the resin due to the negative pressure when the resin is solidified by the growth of the void. [0003] Recently, elastomers are used for many electric appliances and communication devices such as operation buttons arranged on a remote control of a television and operation buttons of a mobile phone.
And when such an elastomer is manufactured by the injection molding method, since the problem of sink occurs in the thick portion as described above, the above-described injection molding method is an effective molding means even in the injection molding of the elastomer. It is considered. [0004] However, when an elastomer is produced by an injection molding method, the temperature control is more difficult than when the elastomer is molded by other thermoplastic resin, and the following problems are caused. Tends to occur. That is, when the elastomer is molded, the temperature range when the molten polymer material is injected and filled into the cavity is very narrow as compared with other cases. Therefore, in addition to difficult temperature control during injection, even if the molten polymer material is injected within a predetermined temperature range, the temperature rises when passing through the gate for injection into the cavity, There is a problem that a large amount of gas is generated from the polymer material. In such a case, resin scorching, gas sinking, deformation, or the like may occur, or a large amount of generated gas may remain as dirt on the surface of the molded product, resulting in deterioration of the appearance quality of the molded product. On the other hand, when the injection temperature of the molten polymer material is lowered and injected into the cavity in order to prevent the adverse effects at high temperatures, the generation of a large amount of gas due to the rapid rise in temperature of the molten polymer material is suppressed. Although it can be performed, the flow of the molten polymer material in the cavity is slowed, so-called insufficient filling or weld line occurs, resulting in impaired appearance quality of the molded product. Accordingly, the present invention utilizes the above-described injection molding method for forming voids to prevent the quality and defects of the elastomer molded product, and to use the above-described void insertion pin when injection-filling a molten polymer material. By utilizing the inside of the cavity to suction and releasing the gas generated from the molten polymer material from the cavity, the gas is prevented from stagnating, the flow of the molten polymer material in the cavity is improved, and resin burns and molded products An object of the present invention is to eliminate surface dirt and improve the appearance quality of an elastomer molded product. [0007] That is, according to the injection molding method for an elastomer molded article according to the present invention, the molten polymer is injected and filled into a cavity in which a void insertion pin is installed. A gas generated from the material is sucked through the void insertion pin, and a pressurized gas is injected through the void insertion pin immediately after the filling of the molten polymer material is completed. When the molten polymer is injected and filled into the cavity at the same time, the inside of the cavity is sucked through the void insertion pin, and the high temperature gas generated by the rise in the temperature of the molten polymer is passed through the void insertion pin. Discharged outside,
Prevent stagnation of hot gas in the cavity. As a result, the temperature rise inside the cavity can be suppressed, and at the same time, the molten polymer material can easily flow in the cavity even at a low injection pressure, so that every corner in the cavity is quickly filled. Although the suction force varies depending on the size of the cavity and the amount of gas generated due to the difference in the type of the molten polymer material, a relatively small suction force is sufficient. In most cases, about -700 mmHg is sufficient. Immediately after the molten polymer material is injected and filled into every corner of the cavity, pressurized gas is injected through the void insertion pin. At this time, the pressurized gas breaks through the skin layer of the molten polymer material being formed at the tip of the void insertion pin, and inserts microbubbles into the molten polymer material to form void nuclei serving as nuclei for void growth. Once the void nucleus is formed, even if the injection of the pressurized gas is stopped, the volume shrinkage force accompanying the cooling and solidification of the surrounding molten polymer material is concentrated on the void nucleus. Therefore, the voids generated using the void nuclei as seeds continue to grow to a size large enough to prevent sink marks while absorbing the volume shrinkage force one after another. As a result, the sink control effect extends not only around the void insertion pin but also to the entire thick portion. At this time, if the injection of the pressurized gas is continued, the volume shrinkage of the molten polymer material and the pressure of the pressurized gas are synergistic to promote the growth of voids, and not only the thick portion but also the peripheral thin portion and the adjacent thick portion. It is also possible to suppress sink marks in the meat portion. The pressure of the pressurized gas for forming voids may be relatively low, and in most cases, pressurization of 10 kg / cm ² or less is sufficient. As the type of the pressurized gas, nitrogen, air, or the like is used at normal temperature. In the present invention, the type of the elastomer to be injection-molded is not particularly limited, and most elastomers such as PVC, styrene, olefin, urethane, polyester, and polyamide are applicable. Next, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. First, the arrangement of the void insertion pins installed in the mold is the same as that of the conventional example shown in FIG. 3. In the case where the cavity 3 is large and suction is insufficient from one location, or the size of the thick portion is large. In the case where only one void is not enough to absorb the shrinkage of the entire thick part, FIG.
As shown in the figure, a plurality of void insertion pins 2 at appropriate distances
It is desirable to install. For example, as shown in FIG. 4, the void insertion pin 2 is inserted into a through-hole 4 opened in the mold 1, and is installed with its tip protruding into the cavity 3. The through hole 4 includes a large diameter portion 5 and a small diameter portion 6, and a difference is provided in an annular space formed between the through hole 4 and the outer peripheral surface of the void insertion pin 2. An air pipe 7 for sucking or pressurizing the inside of the cavity 3 is provided at the rear end of the void insertion pin 2.
Is connected. FIG. 1 is a system diagram of an air pipe 7 connected to the void insertion pin 2 of the mold 1. As shown in FIG. In the system diagram according to this embodiment, an air pipe 7 in which an intake valve 8, a pressure valve 9, and an exhaust valve 10 are connected in parallel to the void insertion pin 2 is provided. A vacuum pump 11 is connected to the intake valve 8.
By controlling 1, the suction force of the cavity 3 can be adjusted. On the other hand, a regulator 12 and a pressure increasing valve 13 are connected in series to the pressurizing valve 9, and air supplied from an air source 14 is supplied to the regulator 12 and the pressure increasing valve 1.
The pressure is adjusted by 3. Note that a check valve 15 for preventing backflow is connected to the exhaust valve 10. FIG. 2 is a timing chart showing the opening and closing times of the valves 8, 9, and 10 connected to the void insertion pin 2. As shown in FIG. First, when a mold clamping signal is output by fixing the fixed mold and the movable mold of the mold 1, the intake valve 8 is switched and opened, and the operation of the vacuum pump 11 causes the cavity 3 to be opened via the void insertion pin 2. Begins to be sucked. Immediately after the suction is started, an injection signal is output, and the molten polymer material is injected and filled in the cavity 3.
Since the suction in the cavity 3 by the intake valve 8 is continued while the molten polymer is injected and filled, the gas generated from the molten polymer is effectively sucked and stays in the cavity 3. Therefore, the flow of the molten polymer material in the cavity 3 is improved. On the other hand, the timer 1 operates simultaneously with the output of the molten polymer material injection signal, and counts the injection filling time of the molten polymer material. After counting for a predetermined time, the intake valve 8 is switched again and closed. At the same time, the pressure valve 9 is opened and the regulator 1 is opened.
2 and the pressurized gas adjusted by the pressure increasing valve 13 are injected into the cavity 3 from the tip of the void insertion pin 2. The opening time of the pressurizing valve 9 is controlled by the timer 2, and after a lapse of a predetermined time, the pressurizing valve 9 is closed and the injection of the pressurized gas is stopped. Finally, the exhaust valve 10 is opened, and the residual air in the void is naturally exhausted. Next, a process for producing an elastomer molded article by the above-described injection molding method will be specifically described. A polymer material as an elastomer material is injected into the cavity 3 of the mold 1 in a molten state from an injection molding machine via a gate to fill the cavity 3. During the injection, the gas generated from the molten polymer is sucked and exhausted by sucking the inside of the cavity 3 through the void insertion pin 2, thereby suppressing the temperature rise of the molten polymer. When the filling of the molten polymer material is completed, pressurized gas is immediately injected through the void insertion pin 2. The pressurized gas concentrates on the tip of the void insertion pin 2 while peeling off the void insertion pin 2 and the surface skin layer of the molten polymer material. When the molten polymer material is cooled and volume contraction starts, the surface skin layer at the tip of the void insertion pin 2 is broken by the pressure of the pressurized gas. At this time, if the void insertion pin 2 has a sharp tip, the thinner the skin layer is, the thinner the skin layer is at the tip of the pin. A hole is formed. Pressurized gas is sent as microbubbles into the molten polymer material, and void nuclei serving as seeds for void growth are formed. The supply of the pressurized gas from the pressurizing valve 9 is stopped at this point. Next, the remaining gas pressure is discharged to the atmosphere by opening the exhaust valve 10. As the cooling step proceeds, the void nuclei are sucked by the volume shrinkage force accompanying cooling and solidification of the surrounding molten polymer material, and gradually grow into voids. At this time, the voids continue to grow in the direction of the molten polymer material whose cooling and solidification is delayed. When the cooling step is completed, the mold 1 is opened and the elastomer molded product is taken out. The obtained elastomer molded product is free from surface resin burns and surface stains due to gas traces.
There is no sink mark on the surface, and the surface has excellent surface properties with the appearance obtained by completely transferring the cavity shape. Next, an embodiment in which an elastomer button is molded by the above-described injection molding method according to the present invention will be described.
This elastomer button is a polyester-based grease E
(Dainippon Ink Co., Ltd.) is used as a resin material, and has a rectangular parallelepiped shape of 13 × 5 × 12 (mm) in height, width, and height, and is formed by taking 10 pieces. While maintaining the mold temperature at about 40 ° C., the resin material is injected for about 3 seconds, and at the same time, the inside of the cavity is suctioned at −700 mmHg. At the same time as the end of the injection of the resin material, the suction in the cavity is stopped, and the mold is naturally cooled for about 15 seconds. During this cooling, pressurized air adjusted to 12 kg / cm ² is fed into the cavity. After the cooling step and the feeding of the pressurized air are completed, the exhaust valve 10
To release the gas remaining in the cavity to the atmosphere. The thus formed elastomeric button is
When compared with a resin molded button of the same shape molded by an injection molding method other than the present invention, no dirt on the surface or sink marks on the surface due to gas traces were observed at all. As described above, according to the injection molding method for an elastomer molded product according to the present invention, a molten polymer material is injected and filled using a void insertion pin for forming a void. In this case, the inside of the cavity is sucked using the above-mentioned void insertion pin, and the gas generated from the molten polymer material is forcibly released from the inside of the cavity. The rise can be suppressed and the gas can be prevented from staying in the cavity. As a result, the temperature control at the time of injection of the molten polymer material can be easily performed, and the surface of the elastomer molded product can be burnt or the surface can be damaged by gas. By removing the stain, the appearance quality of the elastomer molded product could be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an air piping system diagram of an injection molding method for an elastomer molded product according to the present invention. FIG. 2 is a timing chart of valve switching. FIG. 3 is a cross-sectional view of an injection mold using a void insertion pin. FIG. 4 is a structural view of a void insertion pin. [Description of Signs] 1 Mold 2 Void insertion pin 3 Cavity 7 Air piping

Claims (1)

(57) Claims 1. During injection filling of a molten polymer material into a cavity in which a void insertion pin is installed, gas generated from the molten polymer material is passed through the void insertion pin. Injection molding of an elastomer molded article, wherein a pressurized gas is injected through the void insertion pin immediately after the suction is completed and the filling of the molten polymer material is completed.