JP5105613B2 - Injection compression mold - Google Patents

Description

The present invention relates to an injection compression mold, and in particular, a core block provided integrally with a mold body and a side surface forming block whose relative position is changed in the mold opening / closing direction with respect to the core block are the first. The present invention relates to an injection compression molding mold of a type that is provided in a mold and in which a side surface forming block of a first mold is brought into contact with a second mold to form a variable volume cavity.

As an injection compression mold in which a volume-variable cavity is formed between the first mold and the second mold and the molten resin injected into the cavity is compressed, Patent Documents 1 to 3 Those described in (1) are known. Patent Document 1 is a so-called inlay mold, in which a convex part of a movable mold enters a concave part of a fixed mold to form a variable volume cavity. However, Patent Document 1 is a case where the convex portion and the concave portion cannot be accurately fitted to each other due to misalignment when attaching the mold or misalignment of the movable plate with respect to the fixed platen. there were. Further, if the clearance between the convex portion and the concave portion is increased in order to cope with the galling, a large burr is generated during molding.

Moreover, the molding die described in patent document 2 and patent document 3 is known as an injection compression molding die corresponding to the said problem. The molding dies described in Patent Literature 2 and Patent Literature 3 are called flat die, and a side surface forming block whose relative position can be changed relative to the core block of the movable die in the mold opening / closing direction is fixed. A volume-variable cavity is formed by contacting with the mold. However, as shown in Patent Document 2 and Patent Document 3, in the conventional flat mold, a vent (gap) or clearance of about 5 to 20 μm is formed between the core block and the side surface forming block. The sliding is made so as not to cause galling. In particular, Patent Document 3 describes that the occurrence of galling is further prevented by forming a coating layer having high hardness on the outer peripheral surface of the disk plate. However, at the time of molding, there is a problem that molten resin enters the clearance to form burrs. In addition to the case where the burr becomes a problem as a molded product, there are cases where a small piece or powder with a broken burr adheres to other parts or cavities of the molded product.

JP 2001-341177 A (0036, FIG. 1) Japanese Patent Laying-Open No. 2003-145593 (0024, FIG. 3) JP 2002-361688 A (0036, 0037, FIG. 1)

In the present invention, in view of the above problems, an injection compression molding metal that can prevent the occurrence of galling between the side surface forming block and the core block during molding and can prevent the formation of burrs that cause problems in the molded product. The purpose is to provide a mold.

In the injection compression molding mold according to claim 1 of the present invention, the core block provided integrally with the mold main body and the side surface forming block whose relative position is changed in the mold opening / closing direction with respect to the core block are the first. In the injection compression molding mold provided in the mold, the side surface forming block and the second mold are brought into contact with each other to form a variable volume cavity, the side surface forming block is a spring toward the core block. And is fixed to a frame base that is movable in the mold opening / closing direction with respect to the mold main body, and at least one of the inner surface of the side surface forming block and the outer peripheral surface of the core block. Is characterized by wear-resistant processing.

An injection compression molding die according to a second aspect of the present invention is the injection compression molding die according to the first aspect, wherein the inner side surface of the side surface forming block and the outer side surface of the core block are sliding surfaces and are in contact with each other at the cavity side joint portion. It is characterized by that.

An injection compression molding die according to a third aspect of the present invention is characterized in that, in the first or second aspect, the wear-resistant processing is made of WC / C or DLC .

According to a fourth aspect of the present invention, there is provided the injection compression molding die according to any one of the first to third aspects , wherein a through-hole is formed in the side surface forming block in a mold opening / closing direction, and the through-hole is formed. A shoulder bolt whose outer diameter is smaller than the inner diameter of the hole is inserted into the through hole and fixed to the screw hole of the frame base, so that the side surface forming block is fixed to the frame base in an adjustable manner. And

In the injection compression molding mold of the present invention, a core block provided integrally with the mold body and a side surface forming block whose relative position is changed in the mold opening / closing direction with respect to the core block are provided in the first mold. In the injection compression molding mold in which the side surface forming block and the second mold are brought into contact with each other to form a variable volume cavity, the side surface forming block is pressed against the core block by a spring. The mold base is fixed to a frame base that is movable in the mold opening / closing direction, and at least one of the inner surface of the side surface forming block and the outer peripheral surface of the core block is subjected to wear resistance processing. Therefore, it is possible to prevent the occurrence of galling and the formation of burrs that are a problem on the molded product.

The injection compression molding die of the present invention will be described with reference to FIGS. FIG. 1 is a cross-sectional view of an injection compression molding die of a light guide plate according to the present embodiment, and shows a state when the die is brought into contact. FIG. 2 is a front view of the movable mold of the injection compression molding mold of the light guide plate of the present embodiment. FIG. 3 is a cross-sectional view of a main part of an injection compression molding die of the light guide plate of the present embodiment.

An injection compression molding die 11 for a light guide plate of this embodiment is a die for molding a mobile phone light guide plate having a diagonal size of 3 inches and a plate thickness of 0.3 mm by injection compression molding. In the injection compression molding, the interval between the cavity main surface forming surface 18a of the movable mold 12 and the cavity main surface forming surface 42a of the fixed mold 13 is variable between the start of molding and the end of molding, and the volumes of the cavities C1 and C2 are changed. Is to be changed. Therefore, the injection compression molding includes a type called an injection press in which the movable mold 12 is stopped before the mold closing completion position and the movable mold 12 is advanced and compressed as it is after the molten resin is injected. Such injection compression molding is particularly advantageous when molding a light guide plate (the size is not limited) that is thin compared to the area of the light exit surface and the like.

As shown in FIG. 1, an injection compression molding die 11 includes a movable die 12 as a first die and a fixed die 13 as a second die, and both die 12 that are matched with each other. , 13 are formed with cavities C1 and C2 having a variable volume and thickness. A movable mold 12 attached to a movable platen of an injection compression molding machine (not shown) includes a mold main body 15 having a heat insulating plate 14 attached to the movable platen side, a core block 17 on the main body side, and a cavity main surface formation. A core block 16 formed from the core block 18, the runner forming block 19 and the like, and a movable frame portion 22 formed from the frame base portion 20 and the side surface forming blocks 29, 30, 31 and the like are provided.

The surface facing the fixed mold 13 of the core block 18 for forming the cavity main surface, which is provided integrally with the mold main body 15 with the core block 17 on the main body side, is the light output that is one main surface of the light guide plate. It is a cavity main surface forming surface 18a that forms a surface, and has a substantially rectangular shape that substantially matches the shape of the light guide plate to be molded. The cavity main surface forming surface 18a is a mirror surface, but may be a groove or roughened surface. Further, in the core block 18 for forming the cavity main surface, a cooling medium flow path 24 is disposed in parallel with the cavity main surface forming surface 18a so that the molten resin in the cavities C1 and C2 is cooled. Yes. In this embodiment, the core block 18 for forming the cavity main surface is made of stainless steel, which is quenched and tempered steel, and ELMAX (trade name: trade name of Woodeholm: Rockwell C scale hardness (HRC hardness) 57-60) is used. It has been. In addition, STAVAX (trade name of Uddeholm: HRC hardness 52 to 53), stainless steel SUS420J2 (HRC hardness 50 to 54), or the like may be used.

In addition, a runner forming block 19 is integrated with the mold main body 15 between the two core blocks 18 for forming the cavity main surface, which is substantially in the center of the surface of the mold main body 15 on the fixed mold 13 side. Is provided. As shown in FIG. 2, a runner forming surface 19 a is formed on the front surface of the runner forming block 19. Further, as shown in FIG. 1, the runner forming block 19 is provided with a protruding pin 25 of the ejector device so as to be able to move forward and backward through the mold body 15. A cooling medium flow path 26 is formed in the runner forming block 19 so as to surround the protruding pin 25. Further, a gate cutter 27 of a gate cutter device is disposed between the runner forming block 19 and the core block 18 for forming the cavity main surface so as to be able to move forward and backward. The gate cutter 27 of the movable mold 12 may also be coated with WC / C described later.

Concave portions are formed at four locations near the upper and lower four corners on the surface of the mold main body portion 15 on the fixed mold 13 side, and springs 28 are attached to the fixed mold 13 side in the concave portions. Yes. The fixed mold 13 side of the spring 28 is fixed to the frame base portion 20 of the movable frame portion 22 disposed so as to surround the core block 16. The frame base 20 is formed so as to surround the periphery of the core block 17 on the main body side with a certain gap. In addition, a guide rod (not shown) is provided on the mold body 15 toward the fixed mold 13, and the guide rod is inserted into the hole of the frame base 20 so that the frame base 20 can move in the mold opening / closing direction. Guided to stabilize.

As shown in FIGS. 1 to 3, side surface forming blocks 29, 30, and 31 are disposed on the fixed mold 13 side of the frame base portion 20. The side surface forming blocks 29, 30, and 31 have a frame shape that surrounds the core block 18 for forming the cavity main surface together. The inner side surfaces 29b, 30b, 31b of the side surface forming blocks 29, 30, 31 are substantially in contact with the outer side surface 18b of the core block 18 for forming the cavity main surface so that the relative position can be changed at least in the mold opening / closing direction. The front surfaces of the side surface forming blocks 29, 30, 31 are contact surfaces 29 a, 30 a, 31 a with the fixed mold 13. In this embodiment, HPM38 which is prehardened steel is used for the side surface forming block. However, other pre-hardened steel, quenched and tempered steel, martensitic stainless steel SUS420J2 or the like may be used. The side surface forming blocks 29 and 30 except the side surface forming block 31 are pressed by springs 34 and 35 as pressing means toward the core block 18 for forming the cavity main surface. The inner side surfaces 29b, 30b, 31b of the side surface forming blocks 29, 30, 31 are brought into contact with the outer side surface 18b of the core block 18 for forming the cavity main surface as a sliding surface. The side surface forming blocks 29, 30, and 31 may be divided into other numbers. Further, the side surface forming block 30 may be provided with a light incident surface forming block for forming a light incident surface.

Since the relationship between the side surface forming blocks 29 and 30 and the core block 18 for forming the cavity main surface is substantially the same, the relationship between the side surface forming block 30 and the block 18 forming the cavity main surface will be described in detail with reference to FIG. . Above (or below) the frame base 20, a bracket 23 is projected and fixed so as to extend toward the fixed mold 13. A concave portion is formed on the inner side surface of the bracket 23, and a spring 34 as a pressing means is fixed to the concave portion. The tip of the spring 34 is in contact with the outer wall surface of the side surface forming block 30. Further, the side surface forming block 30 is provided with a through hole 32 in the mold opening / closing direction, and a shoulder bolt 33 having an outer diameter smaller than the inner diameter of the through hole 32 is inserted and fixed to the screw hole of the frame base 20. . Accordingly, the side surface forming block 30 is fixed to the frame base portion 20 while being pressed toward the center direction of the core block 18 for forming the cavity main surface. The pressing force by the side surface forming block 30 can counter the injection resin pressure in the cavity C1 by adjusting the spring 34 or another fixing bolt to slightly move the position of the shoulder bolt 33 in the through hole 32. In addition, it is possible to adjust to an appropriate pressing force that does not hinder the sliding of the sliding surfaces 18b1 and 30b2.

As shown in FIG. 2, in this embodiment, the inner side surface 30 b of the side surface forming block 30 is pressed toward the side surface 29 c of the side surface forming block 29 in addition to the core block 18 for forming the cavity main surface. The side surface forming block 29 is pressed toward only the core block 18 for forming the cavity main surface by using the spring 35. However, only one side surface forming block 29 may be pressed against the core block 18 by a spring, whereby the side surface forming blocks 29 on both sides may be pressed against the core lock 18. Therefore, in the present invention, not all the side surface forming blocks may be pressed against the core block, and the side surface forming blocks to be pressed may be at least one or more. The pressing means may be one that is pressed by tightening a bolt other than a spring, or one that is movable in the direction orthogonal to the mold opening / closing direction by an actuator such as a cylinder. Furthermore, the gap between the core block and the side surface forming block is normally opened at a constant interval by a spring, but the side surface forming block is perpendicular to the mold opening / closing direction with respect to the core block by being guided by the other mold when the mold is closed. The side surface forming block may be moved in the direction away from the core block by the spring force of the spring again when the mold is opened.

The front surface of the side surface forming block 30 facing the fixed mold 13 is a contact surface 30a with the fixed mold 13, and the front side portion (the portion closer to the fixed mold 13) of the inner side surface 30b is the cavity side surface forming. It is a surface 30b1. A portion of the inner side surface 30b that comes into contact with the core block 18 for forming the cavity main surface in the vicinity of the cavity C1 is a sliding surface 30b2 having a predetermined width (for example, 10 to 20 mm). A slit 30b3 is formed in part near the portion 15 for the purpose of reducing the friction surface and for the purpose of releasing gas. The ratios of the cavity side surface forming surface 30b1 and the sliding surface 30b2 of the side surface forming block 30 are changed by the movement of the core block 18 for forming the cavity main surface.

Further, the outer side surface 18b of the core block 18 for forming the cavity main surface with which the side surface forming block 30 abuts is also a sliding surface. The outer surface 18b of the core block 18 also has a sliding surface 18b1 having a predetermined width on the cavity side, and is in contact with the cavity-side joint 21 facing the cavity C1.

In this embodiment, the outer surface 18b of the core block 18 for forming the cavity main surface is coated with the hard material W and subjected to wear resistance processing. The hard material W is preferably a material having a low coefficient of friction when sliding with the side surface forming block 30 or the like and a high hardness, such as tungsten-based tungsten carbide (WC, W2C, W3C) or tungsten carbide carbon composite (WC / C). ) Is excellent in the coefficient of friction with stainless steel, and is preferably used. In particular, in the case of WC / C, which is a tungsten carbide-based hard material W, the friction coefficient (non-lubricating) with HPM38 and SUS420J2 constituting the side surface forming block 30 and the like is 0.2, and the Beakers hardness is HV1000 to 1800. This is a hard material W that is suitable in terms of cost.

Next, the table shows a sliding test of a metal member without lubrication. In the test, test pieces of different metal materials were attached to an ultra-precision polishing machine (SPEED FAM), and a sliding durability test was performed 10,000 times by rotation and circular motion. As a result, in Samples 1 and 2 that were not subjected to WC / C coating, wear powder and surface flaws were generated. In Samples 3 and 4 that were subjected to WC / C coating, both wear powder, vibration / noise, and surface conditions were observed. Good results were shown.

The outer surface 18b is coated with WC / C by depositing the core block 18 in a vacuum chamber and introducing a WC / C vapor deposition material, an inert gas, etc. It is formed to about 1 to 10 μm. Therefore, if the cavity main surface forming surface 18a is masked, and the core block 18 for forming the main surface of the cavity is placed with the main body portion side as the bottom surface, four side surfaces can be coated simultaneously. In addition, about the abrasion-proof process with respect to the said outer side surface 18b, when performing vapor deposition, the vapor deposition method is not limited, You may finish after performing plating and a thermal spraying process.

In addition to the WC / C, diamond-like carbon (DLC) is also preferably used as the hard material W. Also in the case of DLC, the coefficient of friction (unlubricated) with SUS420J2 is about 0.2, and the beakers hardness is about HV2000 to 4000. In addition, as the hard material W, nitrides such as TiN, TiCN, CrN, and TiAIN can be used, but since the friction coefficient (unlubricated) with SUS420J2 is about 0.4, If possible, a hard material having a friction coefficient of 0.3 or less is preferable in terms of low friction.

In the above description, an example in which wear-resistant processing is performed on the cavity main surface forming core block 18 side has been described. However, the side-forming block 30 and the like may be subjected to wear-resistant processing. It is sufficient that at least one of 30 and the like is subjected to wear resistance processing. However, when performing wear-resistant processing on the side surface forming block 30 or the like, there is a disadvantage that the number of parts to be subjected to wear-resistant processing increases. In addition, it is desirable to change a hard material when performing an abrasion-resistant process on both surfaces. Further, only the portion where the galling is likely to occur in the core block 18 or the side surface forming block 30 may be subjected to wear resistance processing, and there may be a portion where the wear resistance processing is not performed. Further, the side surface of the runner forming block 19 and the inner side surface 31b of the side surface forming block 31 may be subjected to wear processing.

Further, regarding the shape portions such as the outer side surface 18b of the core block 18 for forming the cavity main surface and the inner side surface 30b such as the side surface forming block 30, the slit 30b3 formed on the mold main body 15 side is provided with the core block 18. You may form in the outer side surface 18b. Further, in a state where the core block 18 and the side surface forming block 30 are brought into surface contact on the mold body 15 side and the side surface forming block 30 is pressed, the gap between both sides near the cavity is 2 μm or less. You may make it keep. Alternatively, only a part of the outer side surface 18b of the core block 18 and the inner side surface 30b of the side surface forming block 30 near the cavity is formed as sliding surfaces 18b1 and 30b2, and the gap between the sliding surfaces 18b1 and 30b2 is 2 μm or less. A slit may be formed, or the sliding surface may be a fine wavy surface. Furthermore, an air supply groove is formed in either one of the core block 18 or the side surface forming block 30 in a direction parallel to the cavity main surface forming surface 18a, the air supply groove and the outside of the mold are connected by a pipe line, Release air may be supplied from the gap or groove toward the cavity C1 or the like.

Next, the fixed mold 13 will be described. As shown in FIG. 1, the fixed mold 13 attached to a fixed plate of an injection compression molding machine (not shown) includes a mold body 41 and a block for forming the cavity main surface. 42, an insert block 43, a sprue bush 44, a fixed gate cutter 45, and a contact block 46 are disposed. A heat insulating plate 47 is attached to the fixed plate side of the mold main body 41, and a hole 48 into which a nozzle of an injection device (not shown) is inserted is formed. A locating ring 49 is attached around the hole 48. A cavity main surface forming block 42 is attached to the movable die 12 side of the mold main body 41, and the surface of the cavity main surface forming block 42 facing the movable mold 12 is a cavity main surface forming surface. 42a. In this embodiment, the cavity main surface forming surface 42a is a portion that forms the reflecting surface of the light guide plate, and fine dots are engraved therein. The cavity forming surface may be a stamper disposed on the surface. A cooling medium flow path 50 is formed in the cavity main surface forming block 42 in parallel with the cavity main surface forming surface 42a, and is connected to a temperature controller outside the mold.

An insert block 43 is fixed to the mold body 41 below the cavity main surface forming block 42. A sprue bush 44 is fixed inside the insert block 43, and the tip end surface of the sprue bush 44 and the runner forming surface of the insert block 43 are opposed to the runner forming surface 19 a of the runner forming block 19 of the movable mold 12. Yes. The runner formation surface is a surface that forms the runner P2 together with the runner formation surface 19a. The width of the runner forming surface in the direction orthogonal to the flow direction of the molten resin gradually increases from the portion adjacent to the sprue bush 44 toward the cavities C1 and C2. A cooling medium flow path 51 is formed in the insert block 43 so as to surround the sprue bush 44.

A fixed gate cutter 45 is fixed between the insert block 43 and the cavity main surface forming block 42. The width of the fixed gate cutter 45 in the direction orthogonal to the flow direction of the molten resin is the same as or slightly wider than that of the movable-side gate cutter 27. The movable block 12 side of the contact block 46 is a contact surface 46a that contacts the contact surfaces 29a, 30a, 31a of the side surface forming blocks 29, 30, 31. Note that an air passage (not shown) may be formed between the cavity main surface forming block 42 and the contact block 46 of the fixed mold 13.

Next, the injection compression molding method of the light guide plate using the injection compression molding die 11 of this embodiment will be described. In this embodiment, a light guide plate having a diagonal size of 3 inches and a plate thickness of 0.3 mm is formed by an injection press which is a kind of injection compression molding. By driving a mold clamping device (not shown), the mold is closed by bringing the movable mold 12 attached to the movable plate into contact with the fixed mold 13 attached to the fixed plate, as shown in FIG. The cavities C1 and C2 having variable volumes are formed. Next, when a predetermined delay time elapses, a polycarbonate molten resin at 320 to 380 ° C. (heating tube front temperature) is injected from a nozzle of an injection device (not shown) through a sprue bush 44 at an injection speed of 100 to 400 mm / sec. To do.

When it is detected that the screw has advanced to a predetermined position by injection, a mold clamping device (not shown) is driven to perform mold clamping. When the movable mold 12 is moved forward by driving the mold clamping device, the core block 16 including the core block 18 for forming the cavity main surface is moved forward relative to the side surface forming blocks 29, 30, and 31. The molten resin in C1 and C2 can be compressed. At this time, since the outer surface 18b of the core block 18 is coated with WC / C, the side surface forming blocks 29 and 30 are pressed against the core block 18 by the springs 34 and 35, and the side surface forming blocks 29 and 30 are pressed. Even if the inner side surfaces 29b, 30b, 31b of the 30, 31 and the outer side surface 18b are in a sliding state, the coefficient of friction is low and no galling occurs. Further, since the surfaces on the cavities C1 and C2 side are the sliding surfaces 18b1 and 30b2 and are in contact with the cavity-side joint portion 21, are there any burrs formed on the light guide plate formed of molten resin? Or the burr is not big enough to be a problem.

As the molding is repeated, the cavity main surface forming core block 18 is heated by the molten resin and thermally expanded. However, the side surface forming blocks 29 and 30 are pressed by the springs 34 and 35 and slightly orthogonal to the mold opening / closing direction. Since the core block 18 is thermally expanded, a substantially constant contact state is always maintained even if the core block 18 is thermally expanded. In the above case, the frame base portion 20 of the movable frame portion 22 is not moved, and only the side surface forming blocks 29 and 30 are moved. Therefore, the pressing direction by the spring 28 is always parallel to the mold opening / closing direction, This does not cause galling on the moving surfaces 18b1, 30b2, etc. In the present embodiment, the outer surface 18b of the core block 18 for forming the cavity main surface and the inner surface 30b such as the side surface forming block 30 can be molded without using any lubricant.

When the core block 16 (including the core block 18 for forming the cavity main surface, the gate cutter 27, and the runner formation block 19) moves forward and a predetermined time elapses, the gate cutter 27 moves forward by the gate cutter device, and the gate P3 Disconnect. In the present embodiment, after the gate P3 is cut by the gate cutter 27, the molten resin in the cavities C1 and C2 is not completely held from the injection device side by the driving of the mold clamping device. As the movable mold 12 is advanced, the cavity main surface forming core block 18 and the like move forward relative to the side surface forming blocks 29, 30, and 31, and the molten resin in the cavities C1 and C2 is compressed. be able to. Since the cooling medium flows through the cooling medium flow paths 24, 26, 50, 51, cooling and solidification of the molten resin in the cavities C1, C2, the runner P2, and the sprue P1 proceed. When mold release air is used, the mold release air is applied toward the cavities C1 and C2 before the mold is opened, and the mold release is further promoted together with the pressure release and the mold open. When the pressure is released, the side surface forming blocks 29, 30, and 31 are moved forward relative to the core block 18 for forming the cavity main surface by the force of the spring 28. When the mold is opened, removal is performed by an unillustrated removal robot.

Next, an injection compression molding die for a light guide plate according to another embodiment will be described with reference to a cross-sectional view of the main part of FIG. In FIG. 4 showing another embodiment, the same members as those of the previous embodiment are denoted by the same reference numerals, and only differences will be described. In another embodiment, a strip-shaped protrusion 61 is provided in a portion adjacent to the side surface forming block 30 or the like of the core block 18 for forming the cavity main surface. The ridge portion 61 is composed of a top surface portion 61a and a slope portion 61b, the height of which is 20 to 100 μm, and the width of the base portion is 20 to 200 μm. The outer surface of the protrusion 61 is a sliding surface 18b1, and is coated with WC / C or the like. The protrusion 61 may be formed only between both side portions of the cavity main surface forming core block 18 and the side surface forming blocks 29 and 29 where burrs are most likely to occur.

If the protruding portion 61 is formed, the spring 34 and the like of the side surface forming block 30 are slightly contracted by the resin pressure at the time of injection, and the space between the sliding surfaces 18b1 and 30b2 is slightly opened, and the portion is burred. Even if the burrs are formed, the burrs are formed at a position lower than the light exit surface of the light guide plate, so that the burrs hardly cause a problem. Further, if the pressing force of the spring 34 or the like is too strong, there is a possibility that the sliding surfaces 18b1 and 30b2 and the like are crushed and the side surface forming block 30 and the like cannot be moved smoothly. The pressing force of the spring 34 and the like need not be stronger than necessary. Even in the above-described case, a problem burr is not formed.

Although the present invention is not enumerated one by one, it is not limited to that of the above-described embodiment, and it goes without saying that the present invention is applied to those modified by a person skilled in the art based on the gist of the present invention. is there. In the above-described embodiment and another embodiment, the first mold is the movable mold 12 and the second mold is the fixed mold 13. However, the first mold is the fixed mold. The second mold may be a movable mold. The first mold and the second mold may be an upper mold and a lower mold of a vertical injection molding machine (one of which is a movable mold and the other is a fixed mold).

Moreover, the molded product molded by the injection compression molding die is not limited to the light guide plate, and is not limited to a disk substrate, a lens, various panels, various frames, automobile parts, and the like. Further, the type of resin is not limited for the molding material, and a material other than resin may be used.

It is sectional drawing of the injection compression molding metal mold | die of the light-guide plate of this embodiment, Comprising: It is a figure which shows the state at the time of type | mold contact. It is a front view of the movable metal mold | die of the injection compression molding metal mold | die of the light-guide plate of this embodiment. It is sectional drawing of the principal part of the injection compression molding metal mold | die of the light-guide plate of this embodiment. It is sectional drawing of the principal part of the injection compression molding metal mold | die of the light-guide plate of another embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Injection compression mold 12 Movable mold 13 Fixed mold 15 Mold main-body part 16 Core block 18 Core block for cavity main surface formation 18a Cavity main surface formation surface 18b Outer side surface 18b1, 30b2 Sliding surface 22 Movable frame part 29, 30, 31 Side surface forming block 29b, 30b, 31b Inner side surface C Cavity W Hard material

Claims (4)

A core block provided integrally with the mold main body and a side surface forming block whose relative position is changed in the mold opening / closing direction with respect to the core block are provided in the first mold, and the side surface forming block and the second mold are provided. In an injection compression molding die in which a cavity with a variable volume is formed by contacting the mold,
The side surface forming block is fixed to a frame base provided to be movable in the mold opening and closing direction with respect to the mold main body in a state of being pressed by the spring toward the core block,
An injection compression molding die, wherein at least one of an inner side surface of the side surface forming block and an outer peripheral surface of the core block is subjected to wear resistance processing. 2. The injection compression molding die according to claim 1 , wherein an inner side surface of the side surface forming block and an outer side surface of the core block are sliding surfaces and are in contact with each other at a cavity side joint portion. The injection compression molding die according to claim 1 or 2 , wherein the wear-resistant processing is made of WC / C or DLC. A through hole is formed in the side surface forming block in the mold opening / closing direction, and a shoulder bolt having an outer diameter smaller than the inner diameter of the through hole is inserted into the through hole and fixed to the screw hole of the frame base. 4. The injection compression molding die according to claim 1, wherein the side surface forming block is fixed to the frame base in an adjustable manner.

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