JP4628476B2 - Injection molding equipment - Google Patents

Description

  The present invention relates to an injection molding apparatus using a mold for molding a resin product.

  At present, many resin products are manufactured by injection molding. This is a process in which resin melted by an injection device is injected and filled in a mold, cooled and solidified in the mold, and then taken out. By the way, the resin product manufactured in this way shrinks at the stage of cooling and solidification due to the characteristics of the resin physical properties, and in the case of a complicated shape, it is pulled by the thick part and so-called sink occurs on the surface, Or even if it is a simple lump shape, since a void will generate | occur | produce inside, it may become a defective product as goods. Therefore, various injection molding apparatuses and injection molding methods for preventing the occurrence of sink marks and voids have been proposed.

  For example, in Patent Document 1 below, in an injection molding apparatus that pressurizes and fills a molten material through a gate into a cavity formed by a fixed mold and a movable mold, the cavity is transferred to the fixed mold. A technique has been disclosed which aims to make a molded article with high accuracy by compressing a portion of the resin where the internal pressure is insufficient by providing a moving core that goes in and out of a part of the inside. Also, in Patent Document 2 below, a slide mechanism having a slide core that moves in a direction different from the clamping direction is provided for the mold, and molding is performed by injecting molten thermoplastic resin into the mold cavity. In the molding process, a resin molding method characterized by compressing the resin in the mold cavity via the slide mechanism and an apparatus for carrying out this method are disclosed.

  By the way, in normal injection compression molding, resin is injected with the mold parting opened, and after completion of filling, the mold is fastened at high pressure to produce a product. In this method, since the parting is open at the time of injection filling, the resin leaks and the resin is sandwiched or the filling is insufficient. In order to prevent the resin leakage, the entire parting needs to have an inlay structure, and there is a disadvantage that the mold becomes complicated and the mold manufacturing cost increases. In order to solve this problem, Patent Document 3 below discloses an injection compression molding method and apparatus for preventing the occurrence of burrs. In Patent Document 3, a part of a cavity formed between a fixed mold and a movable mold is formed by using a movable core that can be pressed via a pressing means, and formed on the outer side of a molded product in the cavity. It is characterized by sometimes molding without having a sliding surface. The movable parting can be closed by the hydraulic cylinder, and the movable piece (moving core) returns to its original state when compression is applied.

JP-A-9-323340 JP-A-8-323827 Japanese Patent Laid-Open No. 7-241890

  However, the background art as described above has the following disadvantages. First, in the techniques described in Patent Documents 1 and 2, a separate circuit such as a hydraulic pressure or a gas pressure is required to move the moving core, and an incidental facility is required. In addition, since it is necessary to add a moving core structure in the mold, the mold becomes large and complicated, the size of the device is limited and high pressure cannot be applied, and the quantity, size, and proximity of the compression points There is a disadvantage that there is a limit. Furthermore, since it is an auxiliary treatment of a portion where a relatively uniform wall pressure is not applied, it cannot cope with an extremely thick or uneven portion.

  On the other hand, in the injection compression molding described in Patent Document 3, it is basically necessary to flatten the parting, which is not suitable for a complicated shape. Moreover, the structure of the slide piece which releases the undercut part which is the merit of an injection mold cannot be applied. Furthermore, although the compression direction is the mold clamping direction, even if the entire product can be compressed, it is not possible to compress only a part, so if there are ribs or uneven thickness in the product, the difference in resin pressure is overcome. There is also the inconvenience that it cannot be done. For this reason, the use is limited to the molding of relatively simple shapes (lenses, light guide plates, compact disks, etc.).

  The present invention pays attention to the above points, and without complicating or increasing the size of the apparatus or the mold, the desired part of the product can be applied at high pressure regardless of the presence or absence of thick or uneven parts. It is an object of the present invention to provide a compressible injection molding apparatus.

The present invention relates to a mold in which a cavity into which molten resin is injected and filled when the first mold plate and the end face of the second mold plate are brought into contact with each other, and the first mold plate to the second mold plate. A mold clamping mechanism that opens and closes the mold by making a stroke with respect to the mold plate; and an injection unit that injects and fills the molten resin into the cavity. The mold supports a first mold plate that supports the first mold plate. The mounting plate is connected to the mold-clamping mechanism and is disposed so as to be able to stroke with respect to the second template supported by the second mounting plate. A molding hole is provided which extends and opens at an end surface facing the second template, and forms the cavity when the end surface is brought into contact with the end surface of the second template. the holes, with a portion of the slide core is slidably received, said first Or it is fixed to at least one of the second template, and is arranged between the leg portions extending in the stroke direction toward the respective mounting plates, and the leg portions and the mounting plates facing the end surfaces thereof. A spacer that supports the template with the legs fixed through the legs, a spacer that can slide in parallel with the mounting plate, and a slide mechanism that slides the spacer in parallel with the mounting plate. In conjunction with the change in the support position of the template from the mounting plate due to the slide of the spacer , the pushing means for relatively changing the position of the slide core in the cavity, and the product is pushed out from the molding hole and released. Mold releasing means, releasing the clamping pressure of the first and second mold plates by the clamping mechanism and relatively changing the position of the slide core in the cavity by the pushing means. After the, by performing the re-clamping by the mold clamping mechanism in a state of closing the mold by the slide cores, characterized by compressing the volume of the cavity. The above and other objects, features and advantages of the present invention will become apparent from the following detailed description and the accompanying drawings.

According to the present invention, a slide core is provided that is slidable in a cavity formed by contact between the first and second mold plates, and the mold clamping pressure of the first and second mold plates is released by the mold clamping mechanism. Then, after the position of the slide core in the cavity is relatively changed by the pushing means, the volume of the cavity is compressed by the slide core while the mold is closed by sliding the slide core by the mold clamping mechanism. It was decided. For this reason, it is possible to compress a desired portion of the product at a high pressure without complicating or increasing the size of the apparatus or the mold, and regardless of the presence or absence of thick or uneven portions.

It is a partial external appearance sectional view which shows an example of the metal mold | die utilized with the injection molding apparatus of Example 1 of this invention. It is a flowchart which shows the molding point by the injection molding apparatus of the said Example 1. FIG. It is a figure which shows the state which pushed in the resin in a cavity with the slide core of the metal mold | die of the said Example 1. FIG. It is a figure which shows the retracted position of the movable side of the metal mold | die of the said Example 1. FIG. It is a figure which shows the mold release state of the product shape | molded in the said Example 1. FIG. It is a figure which shows the pushing amount of an experiment example. It is a figure which shows the sink ratio of an experiment example and a comparative example. It is a figure which shows the amount of sink marks of an experiment example and a comparative example. It is a figure which shows the whole structure of the injection molding apparatus of the said Example 1. FIG. It is a partial external appearance sectional view which shows the metal mold | die of the injection molding apparatus of Example 2 of this invention. It is a partial external appearance sectional view which shows the metal mold | die of the injection molding apparatus of Example 3 of this invention. It is a partial external appearance sectional view which shows the metal mold | die of the injection molding apparatus of Example 4 of this invention. It is a partial external appearance sectional view which shows the metal mold | die of the injection molding apparatus of Example 5 of this invention. It is a figure which shows the time-dependent change of the die temperature at the time of the shaping | molding process by this invention, (a) is a figure which shows the case of a hydraulic type, (b) is a figure which shows the case of an electric type. It is a partial external appearance sectional view which shows the metal mold | die of the injection molding apparatus of Example 7 of this invention. It is a figure which shows the whole structure of the injection molding apparatus of Example 8 of this invention. It is a partial external appearance sectional view which shows the metal mold | die of the injection molding apparatus of Example 9 of this invention. It is a figure which shows the injection molding apparatus of Example 10 of this invention, (a) shows a clamping state, (b) is a figure which shows a re-clamping state.

  Hereinafter, the best mode for carrying out the present invention will be described in detail based on examples.

  First, Embodiment 1 of the present invention will be described with reference to FIGS. FIG. 1 is a partial external cross-sectional view showing an example of a mold used in the injection molding apparatus of the present embodiment. FIG. 2 is a flowchart showing a molding procedure according to this embodiment, and FIG. 3 is a diagram showing a state in which the resin in the cavity is pushed in by the slide core of the mold. FIG. 4 is a view showing a retracted position on the movable side of the mold, and FIG. 5 is a view showing a released state of the molded product. FIG. 6 is a diagram illustrating the indentation amount of the experimental example, FIG. 7 is a diagram illustrating the sink ratio of the experimental example and the comparative example, and FIG. 8 is a diagram illustrating the sink amount of the experimental example and the comparative example. FIG. 9 is a diagram showing the overall configuration of the injection molding apparatus of the present embodiment. As shown in FIG. 9, the injection molding apparatus 100 of the present embodiment includes a mold 110, an injection apparatus 120, and a mold clamping mechanism 130.

  First, the mold 110 will be described. On the fixed side of the mold, the fixed-side mold plate 12 is attached to the fixed-side mounting plate 10, and the sprue bush 14 penetrates the fixed-side mounting plate 10 and the fixed-side mold plate 12. Is provided. A nozzle 128 of an injection device 120 described later is connected to the sprue bush 14 to supply molten resin (see FIG. 9). The fixed-side template 12 is provided with a cooling passage 16 through which a coolant flows along a surface corresponding to a movable-side molding hole 23 described later.

  The movable side includes a movable side mounting plate 20, a movable side mold plate 22 whose front end face faces the fixed side template 12, and a block 30 that fixedly supports the movable side template 22. The block 30 includes a cover plate 32 that covers the back surface of the movable side template 22, and a leg 34 that extends from the cover plate toward the movable side mounting plate 20. A spacer is provided between the leg 34 and the movable side mounting plate 20. 40 is provided. The movable side mounting plate 20 is connected to a rod 136 of a hydraulic cylinder 132 of a mold clamping mechanism 130 described later (see FIG. 9), and can move forward and backward (stroke) toward the fixed side. The movable side plate 22 and the cover plate 32 of the block 30 are provided with a molding hole 23 corresponding to the cross-sectional shape of the product main body to be molded, and a slide core 64 is inserted into the molding hole 23. Yes.

  A branch recess 24 corresponding to a thin branch extending from the product main body and a runner recess 25 for guiding a molten resin are formed on the front end surface of the movable mold plate 22 connected to the molding hole 23. Further, the movable side mold plate 22 is provided with a rod hole 26 extending from the runner concave portion 25 toward the back surface, and the spring accommodating portion 27 whose axial center coincides with the rod hole 26 from the movable side mold plate 22 to the cover plate 32. Is provided. The spring accommodating portion 27 has a bottom wall 36 on the back side of the cover plate 32, and the bottom wall 36 is provided with a through hole 38 whose axial center coincides with the rod hole 26 of the movable side template 22. The movable side template 22 is also provided with a cooling passage 28 surrounding the molding hole 23, and a cooling passage is also provided in the slide core 64 as necessary.

  The leg portion 34 of the block 30 extends from the side edge portion of the cover plate 32 toward the movable mounting plate 20 while avoiding the openings of the molding hole 23 and the through hole 38. A spacer 40 is sandwiched between the tip of the leg portion 34 and the movable side mounting plate 20.

  The cover plate 32 protrudes laterally from the movable side mold plate 22, and a mold holding wall 50 extends from the movable side mounting plate 20 to the front of the cover plate 32. At the front end of the mold holding wall 50, a spring receiving portion 52 having a recessed spring support hole 53 is provided so as to face the front surface of the cover plate 32. A spring 54 held in the spring support hole 53 is provided between the spring receiving portion 52 and the cover plate 32 to urge the movable side mold plate 22 and the block 30 which are connected and fixed to each other toward the movable side mounting plate 20. ing.

  The mold holding wall 50 and the spring 54 are provided at a plurality of locations around the cover plate 32, for example, on each side when the planar shape of the cover plate 32 is a quadrangle. As a result, the movable side mold plate 22, the block 30 and the spacer 40 are unitized and can be displaced together with the movable side mounting plate 20 with respect to the fixed side. The block 30 can be displaced with respect to the movable mounting plate 20 along the mold holding wall 50.

  The contact surface 41 of the spacer 40 with the leg portion 34 of the block 30 is inclined, and the spacer 40 has a rust shape in which the inner side is thinner than the outer side. The spacer 40 includes a screw hole 42 that meshes with a screw shaft 45 extending from the motor 44, and can slide on the movable side mounting plate 20 by driving the motor 44. The motor 44, the screw shaft 45, and the screw hole 42 of the spacer 40 constitute a spacer driving mechanism (sliding mechanism). Note that the spacer driving mechanism using the motor 44 is an example, and a mechanism that slides by connecting the rod 114 to the spacer 40 using the hydraulic cylinder 112 as in the example shown in FIG. In this embodiment, since a hydraulic cylinder is used as the mold clamping mechanism 130 as will be described later, the molding process in FIG. 2 is performed using a timer by using the hydraulic cylinder 112 for the spacer driving mechanism. It becomes possible to manage.

  A slide base 60 is disposed in a space between the spacer 40 and the leg portion 34 of the block 30. The slide base 60 includes a first plate 61 and a second plate 62. A slide core 64 to be inserted into the mold hole 23 of the movable plate 22 and the cover plate 32 is attached to the first plate 61 by a bolt 65 and a pusher 66 corresponding to the through hole 38 of the cover plate 32 is attached. It has been. The second plate 62 covers the bolt hole that appears on the back surface of the first plate 61 and holds the head of the pusher 66.

  The slide core 64 has a function of pushing in the resin in the molding process of the resin in the molding hole 23 and extruding the product resin after cooling from the molding hole 23. Although not particularly shown, a return spring may be provided between the slide base 60 and the cover plate 32 so as to bias the slide base 60 toward the movable mounting plate 20.

  In a state where the motor 44 is driven and the spacer 40 is pushed into the predetermined position, the distance between the cover plate 32 and the movable side mounting plate 20 becomes the first distance. When the movable side template 22 is brought into contact with the fixed side template 12, the space between the slide core 64 and the fixed side template 12 in the molding hole 23 becomes a cavity C filled with resin. The axial length of the cavity C, that is, the distance between the fixed side template 12 facing the molding hole 23 and the front end surface of the slide core 64 is set to be longer than the axial length of the product main body by a predetermined amount. ing.

  The movable side mounting plate 20 is provided with a rod hole 21 through which a protruding rod 70 extending from a hydraulic cylinder 68 (see FIG. 9) passes, and the slide core 64 can be slid by pushing the slide base 60 with the protruding rod 70. It is like that. A runner protrusion rod 73 having a head 74 is inserted into the rod hole 26 of the movable side template 22 on the cover plate 32 side, and the head 74 is attached to the bottom wall 36 of the spring accommodating portion 27 by a spring 76 disposed in the spring accommodating portion 27. Is biased in the direction.

  In a state where the head 74 of the runner protrusion rod 73 is in contact with the bottom wall 36 of the spring accommodating portion 27, a predetermined gap S is provided between the head 74 and the tip of the pusher 66. When the slide core 64 compresses the resin in the cavity C during the molding process, when the pusher 66 that is displaced together with the slide core 64 via the slide base 60 simultaneously presses the runner ejecting rod 73, As a result of the high compression ratio of the resin or the solidification of the runner portion due to the small capacity, the slide core 64 cannot sufficiently compress the product portion in the cavity C. Further, by compressing the runner portion having a small capacity, a load is applied to the gate of the sprue bush 14. For this reason, it is preferable to set the predetermined gap S so that the pusher 68 contacts the runner protrusion rod 73 for the first time after the compression of the product main body by the slide core 64 stops.

  Next, the injection device 120 will be described. As shown in FIG. 9, the injection device 120 melts the molding material charged from the hopper 124 by the cylinder 122 and injects it from the nozzle 128 at the tip of the cylinder 122 to the mold 110 by the injection mechanism 126. Its structure is known.

  The mold clamping mechanism 130 opens and closes the mold 110 by stroking the movable side mold plate 22 with respect to the fixed side mold plate 12, and can apply sufficient pressure when filling with a molding material. ing. Such a mold clamping mechanism includes a direct pressure type and a toggle type. FIG. 9 shows an example using a direct pressure type hydraulic cylinder 132. In the hydraulic cylinder 132, oil chambers 138 and 140 are formed with a piston 134 that can be driven to reciprocate in the hydraulic cylinder 132 as boundaries. The oil chambers 138 and 140 have pressure oil inlets and outlets 142 and 144, respectively. Is provided. One end of a rod 136 is connected to the piston 134, and the other end of the rod 136 is fixed to the movable side mounting plate 20 of the mold 110. The flow path T1 connected to the hydraulic pump 150 branches into two and is connected to the flow paths T2 and T3 via valves V1 and V2, respectively. The flow path T2 is connected to one inlet / outlet 142, and the other flow path T3 is connected to the other inlet / outlet 144.

  Further, in the example shown in FIG. 9, a hydraulic cylinder 112 is shown as a drive mechanism (sliding mechanism) for the spacer 40 of the mold 110, and pressure oil is supplied to and discharged from the hydraulic cylinder 112 by the hydraulic pump 150. You may make it perform. For example, the flow path T4 connected to the hydraulic pump 150 branches into two and is connected to the flow paths T5 and T6 via valves V3 and V4, respectively. The flow path T5 is connected to one of two oil chambers (not shown) of the hydraulic cylinder 112, and the flow path T6 is connected to the other of the two oil chambers (not shown). The switching of the valves V1 to V4 is managed by the timer 152, whereby the spacer 40 can be slid and the movable side of the mold 110 can be moved back and forth at a desired timing.

  Next, the molding procedure by the injection molding apparatus 100 configured as described above will be described with reference to the flowchart of FIG. The molding process starts from a state where the movable side mold plate 22 and the fixed side mold plate 12 are separated from each other with the movable side mounting plate 20 in the retracted position by the hydraulic cylinder 132 of the mold clamping mechanism 130. First, in step S100, the spacer 40 and the protruding rod 70 extending from the hydraulic cylinder 68 are set to the initial positions. That is, the spacer 40 is pushed inward by the spacer drive mechanism, and the distance between the cover plate 32 and the movable side mounting plate 20 is the first distance. Further, the protruding rod 70 is retracted from the front surface of the movable side mounting plate 20.

  In step S101, the hydraulic cylinder 132 is operated to move the movable side mold plate 22 to the fixed side integrally with the movable side mounting plate 20, and is brought into contact with the fixed side mold plate 12 and clamped at a constant pressure. In this state, as described above, the cavity C corresponding to the product main body portion in which the molding hole 23 is closed between the movable side mold plate 22 and the fixed side mold plate 12 by the fixed side mold plate 12 and the slide core 64. Is formed. In a state where the distance between the cover plate 32 and the movable side mounting plate 20 is the first distance, the length of the cavity C, that is, the distance between the front end surface of the slide core 64 and the fixed side mold plate 12 is the same as that of the product main body. It is set longer than the design value of the axial length by a pushing amount described later.

  In the next step S102, molten resin is supplied from the injection device 120 connected to the sprue bush 14 on the fixed side. The molten resin is filled into the cavity C from the nozzle 128 through the sprue bush 14 and the runner recess 25. The previous FIG. 1 shows this state. Even when there is no return spring between the slide base 60 and the cover plate 32, the slide core 64 is pushed by the filled molten resin until the slide base 60 to which the slide core 64 is attached is seated on the movable mounting plate 20. fall back. Thereafter, in step S103, it is checked whether or not a predetermined time has elapsed after filling with the molten resin. During this time, the resin filled in the cavity C is cooled.

  When a predetermined time set in advance elapses, the process proceeds to step S104 to release the mold clamping pressure. In step S105, the spacer 40 is pulled out by a predetermined amount, and a mold clamping pressure is applied again in step S106 (step S110 will be described in Example 10 described later). As a result, as shown in FIG. 3, when the spacer 40 is extracted, the block 30 is relatively displaced toward the movable side mounting plate 20 along the inclination between the spacer 40 and the leg portion 34 of the block 30, and the cover plate 32. And the distance between the movable side mounting plates 20 is shortened to become the second distance.

  As a result, the front end surface of the slide core 64 in the molding hole 23 moves relatively toward the fixed-side template 12 by the difference between the first distance and the second distance, and the resin in the middle of cooling in the cavity C Press to compress. The extraction amount of the spacer 40 is set so that the distance between the front end face of the slide core 64 moved thereby and the fixed-side template 12 becomes the design value of the axial length of the product main body. Since the mold clamping force of the mold clamping mechanism 130 is very large and is incomparable with the force of the hydraulic cylinder that can be incorporated into the mold as shown in the background art, the force of the mold clamping mechanism 130 is By using this to slide the slide core 64 and compressing a desired portion, it becomes possible to form a thick wall that has not been conventionally obtained.

  In step S107, it is checked whether or not a predetermined time for ensuring the completion of cooling has elapsed. When the predetermined time has elapsed, the process proceeds to step S108 and is movable by the hydraulic cylinder 132 of the mold clamping mechanism 130 as shown in FIG. The side mounting plate 20 is returned to the retracted position and the mold is opened. At the retracted position of the movable side mounting plate 20, the fixed side template 12 and the movable side template 22 are separated from each other by a larger distance than the axial length of the product main body.

Thereafter, in step S109, the slide base 60 is pushed out by the protruding rod 70 by the hydraulic cylinder 68 as shown in FIG. A slide core 64 attached to the slide base 60 slides in the molding hole 23 to push out the cooled and molded product main body from the molding hole 23. At the same time, the pusher 66 also pushes the runner portion connected to the product main body portion from the movable side template 12 via the runner protrusion rod 73. As a result, the product P is released and one molding is completed. Note that the timer 152 determines whether or not a predetermined time has elapsed in steps S103 and S107.
<Experimental example>

  Next, the result of measuring the amount of sink for each resin material for an example in which a cube having a side of 70 mm as a product body was molded using the injection molding apparatus 100 of the present embodiment will be shown. Here, ABS, POM (polyacetal), PC (polycarbonate), PMMA (acrylic), PBT (polybutylene terephthalate), and PP (polypropylene) were used as the resin material. The clamping force before and after releasing in step S104 is 150 t (tons).

  The actual pushing amount set for each resin material is shown in FIG. Here, the pushing amount is an amount by which the slide core 64 is slid in the direction of the fixed side template 12 by extracting the spacer 40 outward in step S105. For reference, the theoretical shrinkage calculated from the catalog value corresponding to the above indentation amount when assuming that products of the same cube (each side 70 mm) were made is also shown. The indentation amount is the actual molding temperature and indentation timing. The optimal amount is set in advance by experiments in combination with the above.

  As shown by the solid line in FIG. 7, the sink marks of the products molded with the indentation amount in FIG. 6 are all within 1 to 1.5% except that PP is about 2%. A broken line is a comparative example in the case where molding is performed without pressing, and the distance between the front end surface of the slide core 64 and the fixed-side template 12 is fixed to 70 mm. It can be seen that 8-14% sink marks are generated in the comparative example, whereas the sink marks are remarkably suppressed in the experimental example. FIG. 8 shows the molding result in the case of POM. In the product P ′ of the comparative example, as shown in FIG. 8B, the amount of sink on each side was about 5 mm, but in the product P of the example, As shown to a), it became about 1 mm and significant sink suppression was obtained.

  In the first embodiment, the movable side template 22 corresponds to the first template in the invention, the fixed side template 12 is the second template, and the movable side mounting plate 20 is the first mounting plate. The fixed side mounting plate 10 corresponds to the second mounting plate. Further, the slide core seated on the movable side mounting plate 20 via the slide base 60 by moving the spacer 40 in the pulling direction and changing the support position of the movable side template 22 toward the movable side mounting plate 20. The structure which slides 64 interlockingly comprises the pushing means.

Thus, according to the first embodiment, there are the following effects.
(1) A movable side mounting plate 20 that supports the movable side template 22 is disposed so as to be able to stroke with respect to the fixed side template 12. The movable side template 22 extends in the stroke direction and extends to the fixed side template 12. A molding hole 23 is formed which forms a cavity C that opens to the opposite end face and is injected and filled with a molten resin when the end face is brought into contact with the fixed-side mold plate 12. The slide core 64 is accommodated inside the molding hole 23. To do. Then, after the predetermined time has elapsed after the movable side mold plate 22 and the fixed side mold plate 12 are clamped, the clamping pressure is released, and the position of the slide core 64 in the cavity C is relatively changed by the pushing means. After that, re-clamping is performed by the mold clamping mechanism 130, and the volume of the cavity C is compressed by the slide core 64. At this time, only the necessary portion is compressed by the slide core 64, and the unnecessary portion is projected without being compressed. For this reason, since the desired part of the product can be compressed at a high pressure without complicating or increasing the size of the injection molding apparatus 100 or the mold 110, and with or without thick or uneven parts, It is possible to mold a product that significantly suppresses the generation of voids.

  (2) Since the resin in the cavity C is compressed without opening and closing the parting parts of the movable side mold plate 22 and the fixed side mold plate 12, it is not necessary to complicate the structure of the parting part and is realized at low cost. it can. In addition, since the structure allows injection with the parting closed, it is possible to use molds with undercuts such as slide pieces and inclined pins that are used in conventional molds. Can greatly improve.

  (3) As the configuration in which the volume of the cavity C is compressed by sliding the slide core 64, the movable side mounting plate 20 is moved to the movable side mounting plate 20 via the spacer 40 that can change the support position from the movable side mounting plate 20. Since the position of the slide core 64 in the molding hole 23 is relatively changed in conjunction with the change in the support position of the movable side template 22, the slide can be easily slid by operating the spacer 40. The core 64 can be slid. More specifically, the spacer 40 is provided between the block 30 to which the movable side template 22 is fixed and the movable side mounting plate 20 so as to be movable in parallel with the movable side mounting plate 20 and is in contact with the block 30. Since the surface 41 is an inclined surface and the slide core 64 is seated on the movable side mounting plate 20, the block 30 and the movable side can be moved by moving the spacer 40 in parallel with the movable side mounting plate 20. The side mold plate 22 is displaced along the inclined surface in a direction approaching the movable side mounting plate 20, and the slide core 64 seated on the movable side mounting plate 20 slides in the molding hole 23 in the direction of the cavity C.

  (4) Since the spacer 40 has an inclined surface, the sliding amount of the slide core 64, that is, the pressing amount can be arbitrarily and continuously changed, and the pressing amount appropriate for the shape of the product to be molded, the resin material, etc. The work when obtaining the value by experiment is also simplified.

  (5) A runner ejecting rod 73 is supported on the movable side template 22, and the slide core 64 is seated on the movable side mounting plate 20 via the slide base 60, and the slide base 60 further corresponds to the runner ejecting rod 73. The pusher 66 is attached, and the slide base 60 is pushed out from the seating position on the movable side attachment plate 20 by the protruding rod 70, whereby the slide core 64 releases the product from the molding hole 23, and the pusher 66 is runner. Since the projecting rod 73 is pushed to release the runner, the slide core 64 used for resin compression of the cavity becomes a simple structure also used for product release extrusion.

  At this time, in a state where the slide base 60 is seated on the movable side mounting plate 20, the support position of the movable side mold plate 22 changes between the pusher 66 and the runner protrusion rod 73 during the resin pushing in the cavity C. Even so, since a gap of a distance that does not contact is provided, it is possible to prevent the pusher 66 from pushing the runner protrusion rod 73 when the resin is pushed into the cavity C, and as a result, the runner portion having a small capacity is not compressed. The As a result, it is possible to avoid a situation in which a load is applied to the gate of the sprue bush 14 or a resin pushing amount in the cavity C is insufficient.

  (6) Since the mold clamping pressure is once released before the spacer 40 is moved, no load is applied to the spacer 40 and the durability is improved.

  (7) One hydraulic pump 150 can be shared by using the hydraulic cylinder 112 as the slide mechanism of the spacer 40 and using the hydraulic cylinder 132 as the mold clamping mechanism 130. Further, by providing valves V1 to V4 in flow paths T1 to T6 connecting the hydraulic cylinders 112 and 132 and the hydraulic pump 150, and managing the switching by the timer 152, the slide of the spacer 40 can be performed at a desired timing. The movable side of the mold 110 can be advanced and retracted.

  Next, Embodiment 2 of the present invention will be described with reference to FIG. In addition, the same code | symbol shall be used for the component which is the same as that of Example 1 mentioned above, or respond | corresponds (it is the same also about a following example). FIG. 10 is a view showing the structure of a mold used in the injection molding apparatus according to Embodiment 2 of the present invention. The mold 110A shown in the figure has a structure in which a pressure sensor for measuring the mold internal pressure is provided on the mold 110 shown in the first embodiment. In the example shown in the drawing, a pressure sensor 160A is provided on the fixed-side template 12, a pressure sensor 160B is provided on the movable-side template 22, and a pressure sensor 160C is provided on the slide core 64. These pressure sensors 160A to 160C are arranged on the cavity C side.

  In compression molding, when the internal pressure of a mold shows a constant pressure during compression, sink marks and voids can be controlled and the quality can be stabilized. That is, if the detection results by the pressure sensors 160A to 160C exceed a certain value, voids are not formed. Therefore, the pressure during compression may be increased to such a pressure. In this way, by measuring the internal pressure of the mold 110A, it becomes possible to control sink marks and voids and to stabilize the quality.

  Next, Embodiment 3 of the present invention will be described with reference to FIG. In the mold 110 of Example 1 described above, the contact surface 41 of the spacer 40 that contacts the leg portion 34 is an inclined surface. On the other hand, in the mold 110 </ b> B of the third embodiment shown in FIG. 11, the contact surface 172 of the spacer 170 that contacts the leg 34 is formed to be parallel to the movable side mounting plate 20. As shown in FIG. 11A, in a state where the spacer 170 is pushed inward by the motor 44, the movable side mold plate 22 is brought into contact with the fixed side mold plate 12 to inject the molten resin into the cavity C. When the mold clamping pressure is released after a lapse of time, the motor 44 is driven to extract the spacer 170 outward and apply the mold clamping pressure again as shown in FIG. In the present embodiment, the slide amount of the slide core 64 is controlled roughly by the removal amount of the spacer 170, but the contact surface 172 is flat rather than tapered, so that there is no risk of tilting when clamping the mold. Is obtained.

  Next, Embodiment 4 of the present invention will be described with reference to FIG. In the first embodiment described above, the spacer of the push-in mechanism is provided on the movable side, but this embodiment is an example in which the spacer is provided on the fixed side. As shown in FIG. 12, in the mold 110 </ b> C of the present embodiment, the leg portion 34 of the block 30 is directly fixed to the movable side mounting plate 20, and is provided on the movable side mounting plate 20 in the first embodiment. The mold holding wall 50, the spring receiving portion 52, the spring holding hole 53, and the spring 54 are omitted. On the other hand, the fixed-side template 180 includes a molding hole 184 penetrating in the thickness direction at a position corresponding to the molding hole 23 of the movable-side fixed plate 22, and a part of the slide core 190 is included in the molding hole 184. Is accommodated so as to be slidable in the stroke direction. The slide core 190 is fixed to the fixed side mounting plate 10 via a first plate 192 and a second plate 194.

  Further, a leg portion 186 extending toward the fixed-side mounting plate 10 is fixed to the peripheral portion of the fixed-side template 180. The leg portion 186 is supported by a spacer 40 disposed between the fixed-side mounting plate 10 and the leg portion 186 so that the support position from the fixed-side mounting plate 10 is variable. The receiving portion 188 of the leg portion 186 has a tapered shape, and abuts on the tapered abutting surface 41 of the spacer 40 so as to be slidable. A spring 196 that urges the fixed-side template 180 toward the movable-side template 22 is housed inside the legs 186 and the spacer 40.

  As shown in FIG. 12, with the spacer 44 pushed inward by the motor 44, the movable side mold plate 22 is brought into contact with the fixed side mold plate 180, and the molding holes 23 and 184 and the slide cores 64 and 190 are used. Molten resin is injected into the cavity C to be formed. After the predetermined time has elapsed, when the mold clamping pressure is released, the motor 44 is driven to extract the spacer 40 outward, and the mold clamping pressure is applied again. As a result, when the spacer 40 is extracted, the distance between the fixed side mold plate 180 and the fixed side mounting plate 10 is shortened along the inclination between the spacer 40 and the leg 186, and the slide in the molding hole 184 (or cavity C) is performed. The position of the core 190 moves relatively. Therefore, by sliding the slide core 64 by the mold clamping mechanism and pushing in the resin in the middle of cooling in the cavity C, the same effect as in the first embodiment can be obtained. The sprue bush 14 has a structure that moves relative to the fixed-side mounting plate 10 following the variation in the distance between the fixed-side template 180 and the fixed-side mounting plate 10. The setting of the extraction amount of the spacer 40 is the same as in the first embodiment. The same effect can be obtained by combining the first embodiment and the third embodiment and providing a spacer on both the movable side and the fixed side.

  Next, Embodiment 5 of the present invention will be described with reference to FIG. In this embodiment, a gate seal mechanism for preventing the resin from returning during compression is provided in the mold. In the mold 110 </ b> D shown in FIG. 13A, a through hole 200 is formed that penetrates the movable side mold plate 22 and the cover plate 32 in the stroke direction and reaches the gate recess 25 a that connects the runner recess 25 and the cavity C. . A seal rod 202 is accommodated in the through hole 200, and one end of the seal rod 202 is fixed to the first plate 61 of the slide base 60. The length of the seal rod 202 is set so that the gate recess 25a can be shielded when the product is pushed by the slide core 64. For this reason, at the time of re-clamping (pushing) by the slide core 64, the gate 206 can be shielded as shown in FIG. 13B, and the back flow of the resin from the cavity C to the runner 204 can be prevented. In the present embodiment, the case of the side gate has been described. However, in the case of a pin gate or a tunnel gate, the gate seal mechanism is not necessarily provided. Moreover, you may use the hot runner unit with a gate seal mechanism.

  Next, Embodiment 6 of the present invention will be described with reference to FIG. FIGS. 14A and 14B are diagrams showing a change over time in the mold temperature during the molding process, where FIG. 14A shows a case where a hydraulic mold clamping mechanism is used, and FIG. 14B shows a case where an electric mold clamping mechanism is used. Is shown. In the injection molding using the injection molding apparatus of the present invention, cooling is performed at the same time in the compression process, but in order to prevent deviation in the mold on the product surface that is in contact with the mold in the injection, compression, and cooling processes, FIG. As shown in FIG. 14, the mold temperature is synchronized with the compression process. Specifically, as the temperature of the surface decreases, the surface hardens and becomes wrinkles, so the whole is cooled uniformly. In the case of the hydraulic type shown in FIG. 14 (a), pressure (compression pressure) is first determined because pressure is important. When the pressure is determined, the compression speed is determined, and the mold temperature is also determined. Here, during the first time t, the resin is brought into a state where it does not come out (a state where the resin is not solidified but does not go out dripping). In the case of the electric type shown in FIG. 14B, since the speed is important, first, the compression speed is determined. When the compression speed is determined, the pressure is determined and the mold temperature is also determined. As described above, if the compression process and the mold temperature are synchronized in accordance with the mold clamping mechanism to be used, it is possible to prevent a deviation in the mold on the product surface and to produce a finished product.

  Next, Embodiment 7 of the present invention will be described with reference to FIG. One of the defects that becomes a problem in thick molding is jetting. This embodiment is an example of a mold having a jetting prevention mechanism. In the mold 110 </ b> E of this embodiment shown in FIG. 15A, a spring 210 is provided between the slide base 60 and the slide core 64. One end of the spring 210 is accommodated in a recess 212 formed in the first plate 61. In this embodiment, as shown in FIG. 15A, the slide core 64 is urged toward the fixed-side template 12 by the spring 210, so that the resin starts to be put in a state where the cavity C is narrow. Then, as the amount of resin increases, the slide core 64 gradually moves toward the movable mounting plate 20 against the urging force of the spring 210 as shown in FIG. It is possible to prevent jetting.

  Next, an eighth embodiment of the present invention will be described with reference to FIG. FIG. 16 is a view showing a mold 110F and a drive mechanism 130A of the injection molding apparatus 100A of the present embodiment. If a certain compression pressure is applied to the product, the phenomenon that the resin pressure wins and the parting opens will occur. In this example, in order to suppress the parting opening, a parting opening prevention function is provided. It has a configuration with. In the present embodiment, a flange portion 252 is formed on the periphery of the end surface of the fixed-side mold plate 250, and a flange portion 256 is also formed on the periphery of the end surface of the movable-side mold plate 254. A lock block 260 that holds the convex portion 258 including the flange portions 252 and 256 is disposed outside the fixed-side template 250 and the movable-side template 254. The locking block 260 includes a concave portion 262 that is shaped to fit into the convex portion 258, and has a screw hole 264 on the opposite side of the concave portion 262. Since the screw hole 264 meshes with a screw shaft 268 extending from the motor 266, the lock block 260 can be slid parallel to the fixed side mounting plate 10 by driving the motor 266.

  On the other hand, in this embodiment, a known clamp unit 270 is used as the mold clamping mechanism 130 </ b> A and is connected to the movable side mounting plate 20. The clamp unit 270 includes a motor 272, and the motor 272 is connected to the control device 274. A motor 44 for sliding the spacer 40 and a motor 266 for sliding the locking block 260 are also connected to the control device 274. The control device 274 controls the driving of the motors 44, 266, 272 by referring to the timer 276, and drives the locking block 260 to fit the concave portion 262 to the convex portion 258 during mold clamping. Lock and prevent parting opening. As described above, according to the eighth embodiment, the lock block 260 is provided to prevent resin leakage due to parting opening. In addition, since the controller 274 and the timer 276 are provided to control the driving of the motors 44, 266 and 272, the lock block 260 can be slid at an appropriate timing.

  Next, Embodiment 9 of the present invention will be described with reference to FIG. In each of Examples 1 to 8 described above, the resin is compressed in the stroke direction of the template, but in this example, the resin is applied in a direction perpendicular to the stroke direction, that is, in a direction parallel to the mounting plate. This is an example of a configuration for compression. In the mold 110 </ b> G shown in FIG. 17, a through hole (or a molding hole) 300 extending in a direction perpendicular to the stroke direction is formed in the molding hole 23 of the movable side mold plate 22. A part of 302 is stored. Further, one end of a leg portion 306 extending in the stroke direction is fixed to the movable side mounting plate 20 by a bolt 310. A tapered receiving portion 308 is formed at the other end of the leg 306, and a tapered contact surface 304 is formed at the end of the slide core 302. By bringing the contact surface 304 and the receiving portion 308 into contact with each other, the fixed core mounting plate 10 and the movable mounting plate 20 are connected to the slide core 302 in the through hole 300 in conjunction with the stroke of the movable mounting plate 20. Can be slid in parallel. In addition, a pusher 342 is fixed to the slide base 60 that is seated on the movable side mounting plate 20.

  In this embodiment, the cover plate 322 constituting the block 320 together with the legs 34 supported by the spacer 40 is not provided with the above-described slide core 64 of the first embodiment, and the axial center is made to coincide with the stroke direction. A rod hole 330, a spring accommodating portion 332, and a through hole 334 are formed continuously. The spring accommodating portion 332 has a bottom wall 36 on the back side of the cover plate 322. A product ejecting rod 336 having a head 338 is inserted into the rod hole 330 of the cover plate 322, and the head 338 is biased toward the bottom wall 36 of the spring accommodating portion 332 by a spring 340 disposed in the spring accommodating portion 332. Yes. In a state where the head 338 of the product ejecting rod 336 is in contact with the bottom wall of the spring accommodating portion 332, a predetermined gap is provided between the head 338 and the tip of the pusher 342, and the product is pushed out during compression. First, the extrusion of the product is possible only by the extrusion of the slide base 60 by the ejection rod 70.

  With the above-described configuration, the fixed side mold plate 12 and the movable side mold plate 22 are brought into contact with each other by the mold clamping mechanism to inject molten resin into the cavity C. Is released. When the motor 44 is driven and the spacer 40 is pulled out by a predetermined amount, the mold clamping pressure is applied again by the mold clamping mechanism. Then, the movable mounting plate 20 can be stroked toward the cover plate 322 in accordance with the amount of the spacer 40 extracted, and the slide core 302 slides and resin is moved in conjunction with the stroke of the movable mounting plate 20. Compress. In FIG. 17, the positions of the legs 308 and the slide core 302 after compression are indicated by dotted lines. After the compression is completed, the movable side mounting plate 20 is returned to the retracted position and the mold is opened. Thereafter, by pushing out the slide base 60 from the movable mounting plate 20 with the projecting rod 70, the product ejecting rod 336 is ejected by the pusher 342 attached to the slide base 60 to release the product main body, The pusher 66 projects the runner ejecting rod 73, and the runner part connected to the product main body part is also released from the movable side mold plate 22. As described above, according to the ninth embodiment, in the re-clamping process, the mold clamping mechanism is used to slide in the direction (parallel to the mounting plate 10) perpendicular to the stroke direction of the movable mold plate 22. The core 302 can be slid to perform compression.

  Next, Embodiment 10 of the present invention will be described with reference to FIG. An injection molding apparatus 100B shown in FIG. 18 includes a mold 110H, an injection apparatus 120, and a mold clamping mechanism 130B. In the mold 110 </ b> H, the contact surface 382 of the spacer 380 that contacts the leg portion 34 of the block 30 is formed in parallel to the movable side mounting plate 20. The outer part is formed thicker than the part where the contact surface 382 is formed, and the spacer 380 has a stepped shape as a whole. By providing the step, the inward sliding of the spacer 380 can be restricted. The spacer 380 includes a screw hole 384 that meshes with the screw shaft 45 of the motor 44, and can slide on the movable side mounting plate 20 by driving the motor 44. Further, in the mold 110H of the present embodiment, the mold holding wall 50, the spring receiving portion 52, the spring holding hole 53, and the spring 54 provided in the movable side mounting plate 20 in the first embodiment are omitted. The motor 44 is connected to a switch 366.

  On the other hand, the fixed-side mounting plate 10 is provided with a spacer 390 that can slide on the fixed-side mounting plate 10. The spacer 390 has a stepped shape in which the inner thickness is set thinner than the outer side, and the thin portion can be inserted and removed between the fixed side mounting plate 10 and the fixed side template 12. . The contact surface 392 of the thin wall portion is parallel to the fixed side mounting plate 10. The spacer 390 includes a screw hole 394 that meshes with the screw shaft 398 of the motor 396, and can be slid on the fixed side mounting plate 10 by driving the motor 396. The motor 396 is connected to the switch 400. The thickness of the thin portion of the spacer 390 and the thickness of the thin portion of the spacer 380 are set to be substantially the same.

  A plurality of springs 410 are provided between the fixed side mounting plate 10 and the fixed side template 12. The spring 410 pushes the fixed-side template 12, the movable-side template 22, and the block 30 back to the movable-side fixed plate 20 by the biasing force when the movable-side spacer 380 is pulled out. The position of the slide core 64 in the cavity C is relatively changed, and a gap for inserting the thin portion of the spacer 390 is formed. Note that a spacer 411 disposed between the fixed side template 12 and the fixed side mounting plate 10 is fixed to the fixed side template 12. The spacer 411 defines the amount of contraction of the spring 410. In FIG. 18A, the spring 410 does not contract shorter than the length of the spacer 411.

  The fixed side mounting plate 10 is provided with a recess 401, and one end side of the guide rod 402 is fixed so as not to protrude from the end surface of the fixed side mounting plate 10. The guide rod 402 regulates the stroke amount of the fixed side mold plate 12 by the urging force of the spring 410, and slidably penetrates the through hole 406 provided in the fixed side mold plate 12, and the head 404. The end portion side having the above is housed in a space 408 provided in the movable side template 22. In the guide rod 402, when the spring 410 is contracted, the head 404 is positioned at the back side of the space 408, and when the spring 410 is extended, the head 404 is inserted into the through hole 406 of the fixed side template 12. The relative position in the space 408 changes until it abuts the edge. In the present embodiment, the sprue bush 14 moves with respect to the fixed side mounting plate 10 following the sliding operation of the spacer 390.

  The mold clamping mechanism 130 </ b> B uses a toggle clamp mechanism in which the links 356 to 362 expand and contract by the rotation of the screw 352 connected to the motor 350. The links 356 and 358 are fixed to a fixing member such as a housing, and the links 360 and 362 are fixed to the movable side mounting plate 20. The motor 350 is connected to the switch 364, the motor 44 that slides the spacer 380 of the mold 110 is connected to the switch 366, and the motor 396 that slides the spacer 390 is connected to the switch 400. The switch 366 is connected to a power source 368 and controlled to be switched by a timer 370.

  In this embodiment, as shown in FIG. 18 (a), the movable side template 22 is fixed to the fixed side template while the spacer 380 is pushed inward by the motor 44 and the spacer 390 is pulled out by the motor 396. 12, the molten resin is injected into the cavity C. When the mold clamping pressure is released after a predetermined time has elapsed, the motor 44 is driven to extract the spacer 380 outward. The operation so far is the same as step S105 of the second embodiment. As the spacer 380 is extracted, the spring 410 provided on the fixed side mounting plate 10 extends to push the fixed side template 12, the movable side template 22, and the block 30 back to the movable side mounting plate 20 side. Then, the position of the slide core 64 in the cavity C changes relatively. At the same time, the extension of the spring 410 creates a gap for pushing the spacer 390 on the fixed side.

  Therefore, as shown by the dotted line in FIG. 2, after extracting the (movable side) spacer in step S105, the motor 396 is driven to move the fixed side spacer 390 inward as shown in FIG. After passing through step S110, the process proceeds to re-clamping (step S106) by the mold clamping mechanism 130B. The subsequent operations are the same as steps S107 to S109 in FIG. In the electric molding machine, since the recompression stroke cannot be obtained, in the thick molding, it is necessary to advance the clamp unit at a high speed, but this can be realized by the configuration as in this embodiment.

  In addition, this invention is not limited to the Example mentioned above, A various change can be added in the range which does not deviate from the summary of this invention. For example, in the first embodiment, the portion of the fixed-side template 12 that faces the molding hole 23 of the movable-side template 22 is flat, but the corresponding molding irregularities are formed according to the shape of the product. Can do. Similarly, the surface of the slide core 64 facing the cavity C can also be formed with an uneven portion in accordance with the required shape of the product. Of course, in addition to the slide core 64, a loose core for releasing the undercut portion can be additionally provided for molding a product having an undercut portion. The same applies to the other embodiments. Further, although the cavity and the slide core are provided on the movable side, the present invention is not limited to this, and these may be provided on the fixed side, or may be provided on both sides. Further, in Examples 1 to 5, 7, and 8, the recompression direction is the Stoke direction, and in Example 9, the direction is orthogonal to the stroke direction, but the slide core is slid so as to be inclined with respect to the stroke direction. It is also possible to adopt a configuration in which recompression is performed in an oblique direction.

According to the present invention, a slide core is provided that is slidable in a cavity formed by contact between the first and second mold plates, and the mold clamping pressure of the first and second mold plates is released by the mold clamping mechanism. Then, after the position of the slide core in the cavity is relatively changed by the pushing means, the slide core is slid by the mold clamping mechanism, and the volume of the cavity can be compressed by the slide core while the mold is closed. Therefore, it can be applied to a plastic injection molding device. In particular, because it is possible to apply the required amount of compression to the required location, thick cases, uneven thickness cases, cases with both thick and uneven thicknesses, molding with insert portions with large heat capacity This is suitable for injection molding of cases, relatively long parts (ratio of length to width), products and parts with many molding defects, and parts with a narrow control range of molding conditions.

10: Fixed side mounting plate 12: Fixed side template 14: Sprue bushing 16, 28: Cooling passage 20: Movable side mounting plate 21: Rod hole 22: Movable side plate 23: Molding hole 24: Branch recess 25: Runner recess 25a: Gate recess 26: Rod hole 27: Spring accommodating part 28: Cooling passage 30: Block 32: Cover plate 34: Leg part 36: Bottom wall 38: Through hole 40: Spacer 41: Contact surface 42: Screw hole 44: Motor 45: Screw shaft 50: Mold holding wall 52: Spring receiving portion 53: Spring support hole 54: Spring 60: Slide base 61: First plate 62: Second plate 64: Slide core 65: Bolt 66: Pusher 68: Hydraulic pressure Cylinder 70: Protruding rod 73: Runner ejecting rod 74: Head 76: Spring 100, 10 A, 100B: Injection molding devices 110, 110A to 110H: Mold 112: Hydraulic cylinder 114: Rod 120: Injection device 122: Cylinder 124: Hopper 126: Injection mechanism 128: Nozzle 130, 130A, 130B: Clamping mechanism 132: Hydraulic cylinder 134: Piston 136: Rod 138, 140: Oil chamber 142, 144: Entrance / exit 150: Hydraulic pump 152: Timer 160A to 160C: Pressure sensor 170: Spacer 172: Contact surface 180: Fixed side template 182: End surface 184 : Forming hole 186: leg 188: receiving part 190: slide core 192: first plate 194: second plate 196: spring 200: through hole 202: seal rod 204: runner 206: gate 210: spring 212: recess 250: Fixed side template 252: collar 2 54: movable side template 256: collar 258: projection 260: locking block 262: recess 264: screw hole 266: motor 268: screw shaft 270: clamp unit 272: motor 274: controller 276: timer 300: penetration Hole 302: Slide core 304: Contact surface 306: Leg part 308: Receiving part 310: Bolt 320: Block 322: Cover plate 330: Rod hole 332: Spring accommodating part 334: Through hole 336: Product ejection rod 338: Head 340 : Spring 342: Pusher 350: Motor 352: Screw 354: Fixing members 356 to 362: Links 364 and 366: Switch 368: Power supply 370: Timer 380 and 390: Spacers 382 and 392: Contact surfaces 384 and 394: Screw holes 396 : Motor 398: Screw shaft 400: Sui Chi 401: recess 402: guide rod 404: Head 406: through hole 408: Space 410: Spring 411: spacer C: cavity V1-V4: valve T1 to T6: the flow path

Claims (13)

A mold in which a cavity into which molten resin is injected and filled when the end faces of the first and second mold plates are brought into contact with each other; and the first template is attached to the second template And a mold clamping mechanism that opens and closes the mold, and an injection means for injecting and filling molten resin into the cavity,
The mold is
The first mounting plate that supports the first template is connected to the mold clamping mechanism, and is disposed so as to be able to stroke with respect to the second template supported by the second mounting plate.
The first template extends in the stroke direction and opens at an end surface facing the second template, and the end surface is brought into contact with the end surface of the second template. A molding hole is formed to form a cavity,
A part of the slide core is slidably accommodated in the molding hole,
It is fixed to at least one of the first or second template, and is arranged between the leg portion extending in the stroke direction toward the respective attachment plate, and the leg portion and the attachment plate facing the end surface thereof. A spacer that supports the template with the legs fixed through the legs, and is slidable in parallel with the mounting plate; a sliding mechanism that slides the spacers in parallel with the mounting plate; A pushing means for relatively changing the position of the slide core in the cavity in conjunction with the change in the support position of the template from the mounting plate by sliding the spacer ;
Mold release means for extruding the product from the molding hole and releasing the mold;
Have
The mold clamping pressure of the first and second mold plates by the mold clamping mechanism is released, the position of the slide core in the cavity is relatively changed by the pushing means, and then the mold clamping is performed by the mold clamping mechanism. By performing, the volume of the said cavity is compressed by the said slide core in the state which closed the said metal mold | die, The injection molding apparatus characterized by the above-mentioned. The contact surface between the spacer and the leg is inclined with respect to the mounting plate , and the pushing amount of the slide core can be continuously changed according to the sliding amount of the spacer. The injection molding apparatus according to claim 1 . The contact surface between the spacer and the leg is parallel to the mounting plate,
A step provided on the spacer to restrict the inward sliding of the spacer;
Guide means for prescribing the amount of pushing of the slide core caused by the outward sliding of the spacer;
The injection molding apparatus according to claim 1, wherein:   The slide core is disposed to be seated on the first mounting plate via a slide base, and the volume of the cavity is determined by stroking the slide base together with the first mounting plate by the mold clamping mechanism. The injection molding apparatus according to any one of claims 1 to 3, wherein the is compressed in a stroke direction. The releasing means is
The slide base;
An extrusion mechanism for extruding the slide base from a seating position on the first mounting plate;
Including
The injection molding according to claim 4, wherein the slide core releases the product from the molding hole by pushing out the slide base from a seating position on the first mounting plate by the push-out mechanism. apparatus. The releasing means is
A runner ejection rod supported by the first template,
A pusher attached to the slide base at a position corresponding to the runner protruding rod;
Including
The injection molding apparatus according to claim 5, wherein the product is released from the mold by extruding the slide base by the extruding mechanism, and the pusher pushes the runner ejection rod to release the runner.   In a state where the slide base is seated on the first mounting plate, a distance that does not contact between the pusher and the runner protrusion rod due to a change in a support position of the first template by the pushing means. The injection molding apparatus according to claim 6, wherein a gap is provided. The slide core is supported by legs extending in a stroke direction from the first mounting plate, and is arranged to be slidable in parallel to the mounting plate.
The contact surface of the slide core and the leg portion is inclined with respect to the mounting plate,
Stroke the first mounting plate by the mold clamping mechanism to slide the slide core parallel to the mounting plate, and compress the volume of the cavity in a direction perpendicular to the stroke direction. The injection molding apparatus according to any one of claims 1 to 3.   The injection molding apparatus according to any one of claims 1 to 8, further comprising a pressure sensor that detects an internal pressure in the mold. A gate sealing mechanism that prevents a return of the molten resin by blocking a gate through which the molten resin guided from the injection means passes to the cavity during compression by the slide core;
The injection molding apparatus according to claim 1, wherein the injection molding apparatus is provided.   Using an urging means for urging the slide core in a direction in which the volume of the cavity decreases, the slide core resists the urging force of the urging means according to the amount of molten resin injected into the cavity. The injection molding apparatus according to any one of claims 1 to 10, further comprising a jetting prevention mechanism that prevents jetting by sliding.   The injection molding apparatus according to any one of claims 1 to 11, further comprising a parting opening preventing mechanism that prevents parting opening of the first and second templates. The parting opening prevention mechanism is
A lock block for gripping the flanges formed on the respective edges of the first and second templates together.
A locking slide mechanism for sliding the locking block in a direction perpendicular to the stroke direction;
The injection molding apparatus according to claim 12, comprising:

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