JP4862014B2 - Injection control device - Google Patents

Description

  The present invention relates to an injection control device, and more particularly to an injection control device capable of suppressing generation of a weld line during injection molding.

  Conventionally, when manufacturing various plastic products, by heating at a high temperature, a molten resin having a low viscosity is injected and filled into a cavity of a mold at a high pressure, and the plastic is cooled and solidified in the cavity. Many injection molding techniques for manufacturing products are used. This makes it possible to produce a resin molded product made of a thermoplastic resin such as polypropylene or polyethylene in a relatively simple and low cost manner.

  Here, the injection molding technique will be described more specifically. First, a thermoplastic resin such as polypropylene is heated to a high temperature of about 50 ° C. to 150 ° C. (for example, 180 ° C. to 450 ° C.) from the melting point or glass transition point of the resin. To a molten resin having a low viscosity and fluidity. Then, using an injection unit capable of injecting the molten resin at a high pressure, the molten resin is injected into a cavity of an injection mold that is engraved into a desired shape and filled. At this time, the injection mold is set to a temperature lower than that of the molten resin heated at a high temperature. Therefore, the molten resin injected into the cavity is rapidly cooled by the temperature drop due to the injection and the transfer of heat to the injection mold, and becomes a temperature below the melting point or glass transition point. As a result, the fluidity of the molten resin is impaired, and a phase transition from liquid to fixation is performed. Thereby, the plastic product solidified along the shape of the cavity can be manufactured. Thereby, a molding process can be performed at a relatively low temperature of 500 ° C. or less, and the process from injection filling to cooling and die-molding of the plastic product can be performed in a short time. Therefore, cycle time can be shortened, high production efficiency can be maintained, and mass production can be performed at low cost.

  At this time, it is known that the molten resin filled in the cavity at a high pressure is cooled by an injection mold held at a low temperature, and its fluidity is largely lost during injection filling. Then, utilizing such properties, the molten resin undergoes a phase transition from a liquid to a solid in the cavity to produce a plastic product (resin molded product). Therefore, the larger the distance from the injection port (gate) for injecting and filling the molten resin into the cavity, the greater the phase transition proceeds, and the fluidity of the molten resin is significantly reduced. Therefore, as shown in FIG. 5, in the case of the injection mold 100 having the shape of the cavity 102 in which the molten resin 101 divided in two directions by the obstacle 103 collides with each other and merges, the melt having low fluidity is used. The resins 101 are not sufficiently mixed together, which may cause a problem in the quality of the resin molded product.

  That is, as described above, even if the molten resins having lowered fluidity are stirred at a relatively low temperature and mixed, a so-called “weld line WL” is formed in a region where the two collide with each other. There was a thing. Such a weld line WL is highly likely to be generated due to the property of manufacturing the resin molded product by injection molding the molten resin 101, and the production of the resin molded product that does not exist has been highly expected.

  And this weld line WL has a great influence on the quality characteristics (particularly strength) of the resin molded product and impairs the appearance of the resin molded product. For example, the surface of the resin molded product is coated, In some cases, a post-process (painting process) is required to make the weld line inconspicuous.

  Furthermore, in order to eliminate the weld line WL, it is known that stirring and mixing at the portion where the molten resins join together are performed well by keeping the mold used for injection molding at a high temperature. ing. Alternatively, a method is also known in which high-temperature steam is injected into a mold cavity to keep the temperature in the cavity high, and then rapidly cooled with water after injection filling with molten resin.

  The above-described conventional techniques are naturally implemented by those skilled in the art, and the applicant of the present application does not particularly know documents or the like in which such conventional techniques are described at the time of filing the present application.

  However, the above-described technology related to injection molding may cause the following problems. That is, many resin molded products produced and manufactured by injection molding have complicated shapes, and the behavior related to the flow and filling of the molten resin in the cavity is not constant. In particular, as described above, when there is a location in the cavity that would obstruct the flow of the molten resin, the flow of the molten resin is divided by the obstacle, and the molten resin is joined again. There was a high possibility that a weld line was formed at the location. At this time, although it is recognized that bringing the mold to a high temperature state or ejecting steam before injection filling with the molten resin is effective in suppressing the occurrence of weld lines, It is necessary to cool the mold quickly and solidify the molten resin from liquid to solid to the extent that it can be removed from the mold. Time required for a series of molding cycles from filling the molten resin to removing the mold (cycle time) Inevitably increased. Therefore, there is a problem that the production efficiency per unit time is lowered.

  In addition, it is necessary to provide an ejection mechanism for ejecting steam or the like, and there is a possibility that the injection molding equipment and the mold or the like may require a large amount of cost as compared with the conventional case. Therefore, although it is possible to adopt the above system for a relatively long resin molded product, it has been difficult to apply to a resin molded product with a small production amount or a small molding size.

  Therefore, in view of the above circumstances, the present invention can be molded with a cycle time that is not different from the conventional injection molding technology without requiring special equipment, and is a small-sized resin molded product. It is an object of the present invention to provide a low-cost injection molding apparatus that can be introduced.

In order to solve the above-mentioned problems, the injection control device of the present invention has a “main gate and a sub-gate disposed apart from the main gate, and molten resin is injected into the cavity from the main gate and the sub-gate. Formed by branching from one end of the unit-side runner and connected to the main gate, and a unit-side runner connected to the injection unit for injecting the molten resin heated at a high temperature. A branch runner having a main side runner and a sub side runner connected to the sub gate, a gate opening / closing mechanism portion provided in the sub side runner or the sub gate, for shutting off and releasing injection of the molten resin from the sub gate, Connected to the gate opening / closing mechanism, the injection of the molten resin from the sub-gate is performed by the main gate. The molten resin into the sub-gate from the start of injection is provided with a delay controller for delaying until just before the arrival of the cavity is provided at a position blocking the flow path opposing the molten resin to the main gate, the molten The flow collides with the flow and the flow is blocked, and the flow dividing portion in which the flow dividing region for dividing the molten resin in at least two directions is formed, and the flow of the divided molten resin that collides with the flow divided portion and flows. The sub-gate further includes two or more diversion channels and a mixing space portion in which a mixing region where the molten resin diverted on the end side of the diversion channel is merged is formed, and the sub-gate includes the diversion region and the mixing region Is provided in the middle of one of the branch flow paths that connects to the cavity ”.

  Here, the branch runner is interposed between an existing injection unit and an injection mold, and is a runner that branches in at least two directions from one end of a unit side runner connected to the injection unit (main Side runner and sub-side runner). That is, when the molten resin stored in the injection unit is sent to the branch runner at high pressure, it passes through the unit side runner and reaches the branch point of the main side runner and the sub side runner. Will be injected. As a result, molten resin is injected from the main gate and sub-gate connected to each runner. At this time, a gate opening / closing mechanism section is provided in the sub-side runner or sub-gate, and the injection timing of the molten resin is delayed by a delay control section described later. Therefore, the branched molten resin is initially injected into the cavity only from the main gate, and injection from the sub-gate is started after a predetermined time has elapsed. Here, the number of main side runners and sub side runners branched from one end of the unit side runner is not limited, for example, one main side runner and two sub side runners, or two main side runners. You may change suitably according to the shape of a cavity, such as a runner and two sub side runners.

  Furthermore, the gate opening / closing mechanism is for controlling ON / OFF of injection from the sub-side runner connected to the cavity, for example, a physical method such as an air cylinder or a hydraulic cylinder, or a solenoid valve, etc. As long as it can be opened and closed by this electrical method. However, since the molten resin is injected into the cavity with a delay in injection timing, for example, the molten resin can be injected from the sub-gate at an opening / closing speed (operation reaction speed) of about 1/10 s to 1/100 s depending on the operation. What is to be expected. Here, the gate opening / closing mechanism will be described in more detail. For example, an injection operation switch capable of transmitting an injection signal instructing the start of injection of molten resin from the injection unit, and the injection unit are controlled according to the injection signal Injection control means, a timer that counts the time from pressing of the injection operation switch, and the gate opening / closing mechanism that is electrically controlled according to the time counted by the timer (corresponding to the injection timing), the molten resin from the sub-gate What mainly has a structure such as a gate control means for starting the injection of the ink is exemplified.

Therefore, according to the injection control device of the present invention, the injection of the molten resin from the main gate into the cavity is started, after the lapse of a predetermined time from the start of injection from the main gate, a new molten resin from the sub-gate cavity It is injected in. At this time, the molten resin injected from the main gate is cooled by the flow in the cavity and gradually loses its fluidity. On the other hand, the molten resin injected from the sub-gate with a delay from the injection of the main gate has not yet lost the fluidity because the heat loss does not occur. Therefore, the fluidity (decrease in viscosity) of the molten resin is restored again by mixing and stirring the molten resin that is losing fluidity and the hot (hot) molten resin. As a result, there is no problem such as a weld line generated by low temperature molten resins. Further, the molten resin is divided by the flow dividing portion provided in the cavity, and the molten resin is mixed again in the mixing space portion through the dividing flow path. At this time, by providing the sub-gate in the middle of the branch flow path, at least one of the molten resins mixed with the molten resin again in the mixing space portion includes the high-temperature molten resin injected from the sub-gate, Good mixing and stirring takes place. Therefore, the possibility of occurrence of weld lines is reduced.

  Further, the injection control device according to the present invention, in addition to the above-described configuration, “the gate opening and closing mechanism portion is configured using an electromagnetic solenoid formed so that an extrusion pin can be inserted into and removed from the sub-side runner, The injection of the molten resin from the sub-gate can be adjusted by an extrusion pin.

  Therefore, according to the injection control device of the present invention, it is possible to block and open the injection of the molten resin by inserting / removing the push pin of the electromagnetic solenoid with respect to the sub-side runner. In particular, by using an electromagnetic solenoid, the gate opening / closing mechanism can be electrically controlled, and the insertion / removal speed by the push pin can be increased. Therefore, the injection timing of the molten resin can be finely controlled, and the injection of the molten resin from at least two directions according to the shape of the cavity can be easily performed.

  Therefore, according to the injection control device of the present invention, the injection of the molten resin from the sub-gate is performed immediately before the molten resin injected from the main gate reaches the sub-gate. Accordingly, one of the molten resins to be mixed again in the mixing space as described above necessarily includes a high-temperature molten resin, and it becomes possible to suppress the occurrence of weld lines due to a decrease in fluidity. .

  As an effect of the present invention, molten resin is injected into the cavity from the main gate connected to the main runner, and after a predetermined time has elapsed from the start of injection from the main gate, the injection timing is shifted and the molten resin from the sub-gate is shifted. An injection is started. As a result, the molten resin cooled in the cavity and gradually losing fluidity comes into contact with and mixes with the high-temperature molten resin, whereby the fluidity of the molten resin is restored. In particular, it is possible to suppress the generation of a weld line that occurs when the flow is divided into a plurality of cavities depending on the shape of the cavity and merged again by stirring and mixing the high-temperature molten resin. Thereby, the strength reduction of the resin molded product is suppressed, the appearance aesthetics are not impaired, and the processing such as painting can be omitted.

  Hereinafter, an injection control device 1 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4. Here, FIG. 1 is an explanatory diagram schematically showing a schematic configuration and a functional configuration of the injection control device 1 of the present embodiment, and FIG. 2 is a (a) ladder circuit showing a configuration of the injection control device 1. FIG. 3 is a flow chart showing an example of the flow of injection control by the injection control device 1, and FIG. 4 shows (a) before delayed injection by the injection control device 1, and (b) melting during stirring and mixing. It is explanatory drawing which shows the state of resin.

  As shown in FIGS. 1 to 4, the injection control device 1 of the present embodiment has a cavity 3 engraved in accordance with the shape of a resin molded product (not shown) to be manufactured. An injection mold 6 having a main gate 4 and a sub-gate 5 spaced apart from the main gate 4 and communicating with the molten resin 2 from the main gate 4 and the sub-gate 5 into the cavity 3; A sub-runner connected to the main-side runner 9 and the sub-gate 5 formed by branching from the unit-side runner 8 connected to the injection unit 7 for injecting the molten resin 2 and one end 8 a of the unit-side runner 8. 10 and a sub-runner 10 in the vicinity of the sub-gate 5 to block and release injection of the molten resin 2 from the sub-gate 5. The gate opening / closing mechanism 12 is electrically connected to the gate opening / closing mechanism 12 and delays the injection timing of the molten resin from the sub-gate 5 for a predetermined time from the start of injection of the molten resin 2 from the main gate 4. 13 mainly. In addition, the injection unit 7 can utilize the conventionally well-known thing used for injection molding, and here heats thermoplastic resins, such as a polypropylene, and sets it as the molten resin 2, Detailed description is abbreviate | omitted here. The injection unit 7 and the delay control unit 13 are connected to a power source (not shown) that supplies electric power for operation.

  Here, the injection control apparatus 1 of the present embodiment has a flow path F of the molten resin 2 facing the main gate 4 as shown in FIG. 1 as an injection mold 6 into which the molten resin 2 is injected and filled. Provided at a blocking position, the flow is blocked by the collision of the molten resin 2, and a flow diverting portion 14 is provided for diverting the molten resin 2 in at least two directions (corresponding to the vertical direction on the paper surface in FIG. 1). . Furthermore, a pair of branch flow paths 15a and 15b that collide with the flow splitting portion 14 and flow of the split molten resin 2 flow are formed, and the split molten resin 2 flows on the final path side (downstream side) of the split flow paths 15a and 15b. The thing which has the mixing space part 16 which merges again is illustrated. In addition, the flow diversion part 14 is formed according to the shape of the resin molded product to be molded, and examples thereof include an operation panel used for an operation part of a power window switch for operating an automobile window. be able to. In such a case, the portion corresponding to the hole in which the switch for operation is installed corresponds to the flow dividing portion 14.

  That is, as shown in FIG. 1, when the injection mold 6 is observed from above, a rectangular flow dividing portion 14 is provided near the center of the cavity 3 having a substantially rectangular shape, and above and below it. Branch channels 15a and 15b are formed, respectively. And the mixed space part 16 where the molten resin 2 joins again and is stirred and mixed is formed downstream of the diversion channels 15a and 15b (on the right side in FIG. 1). That is, a flow dividing region S where the molten resin 2 flows (branches) is formed on the upstream side (the left side in FIG. 1) of the flow dividing portion 14, and the mixing region M is formed in the mixing space portion 16 on the downstream side. (See FIG. 4).

  A sub-gate 5 is provided in the middle of one branch channel 15a that connects the shunt region S and the mixing region M so as to communicate with the cavity 3, and is connected to the sub-side runner 10 as described above. Yes. As described above, the gate opening / closing mechanism 12 is installed in the sub-side runner 10 in the vicinity of the sub-gate 5. More specifically, an electromagnetic solenoid 19 having an extrusion pin 18 formed so as to be detachable from the solenoid body 17 is used as a main configuration of the gate opening / closing mechanism section 12, and a portion of the extrusion pin 18 is a sub-side runner. 10 so as to protrude with respect to 10. Therefore, the molten resin 2 injected from the injection unit 7 by the extrusion pin 18 and branched to the sub-side runner 10 is in a state where the extrusion pin 18 is inserted into the sub-side runner 10, in other words, the sub-side runner 10. In the state where is blocked, the sub-gate 5 does not inject into the cavity 3. On the other hand, the molten resin 2 can be freely injected from the sub-gate 5 in a state where the push pin 18 is accommodated on the solenoid body 17 side, in other words, in a state where the sub-side runner 10 is opened.

  Further, a delay control unit 13 for electrically controlling the gate opening / closing mechanism unit 12 including the electromagnetic solenoid 19 is connected. Thus, the injection timing of the molten resin 2 from the sub-gate 5 can be freely controlled. Here, the functional configuration of the delay control unit 13 will be described with reference to FIGS. 1 and 2. The delay control unit 13 is electrically connected to the gate opening / closing mechanism unit 12 and the injection unit 7, respectively. Based on the injection operation switch 20 for performing an operation for starting the injection of the molten resin 2 from the injection unit 7 and the operation signal SG transmitted according to the operation by the injection operation switch 20, the time from the start of the injection is measured. A timer 21 that performs the control, a main injection control means 22 that performs control for injecting the molten resin 2 from the injection unit 7 to the cavity 3 based on the operation signal SG, and a time that is set in advance based on the time measurement by the timer 21. Upon detection, the push pin 18 of the electromagnetic solenoid 19 provided as the gate opening / closing mechanism 12 is pulled out from the sub-runner 10 and the molten resin 2 is removed. The sub-injection control means 23 that enables the flow of the toner runner 10 and the injection stop means 24 that stops the injection of the molten resin 2 from the main gate 4 and the sub-gate 5 by the injection unit 7 based on the count by the timer 21. And is mainly configured. Thereby, the injection of the molten resin 2 from the sub-gate 5 is started with a predetermined time delay from the start of the injection of the molten resin 2 from the main gate 4.

  Next, an example of injection control by the injection control device 1 of the present embodiment will be described based on FIGS. 3 and 4. First, the injection operation switch 20 constituting the delay control device 13 is operated to generate an injection signal SG (step S1). Thus, the timer 21 starts counting based on the operation signal SG (step S2). That is, the elapsed time LT after the injection operation switch 20 is operated is counted. Based on the injection signal SG, the start of injection of the molten resin 2 into the cavity 3 by the injection unit 7 is controlled (step S3). As a result, the molten resin 2 is sent out from the injection unit 7 through the branch runner 11 and injected into the cavity 3. At this time, the main gate 4 is opened according to the initial setting conditions, and the molten resin 2 can be injected into the cavity 3. On the other hand, the electromagnetic solenoid 19 of the gate opening / closing mechanism unit 12 is connected to the sub-side runner 10 with an extrusion pin. Since 18 is inserted, the sub-gate 5 (sub-side runner 10) is cut off. Therefore, the flow of the molten resin 2 that has flowed to the sub-runner 10 of the branch runner 11 is restricted by the extrusion pin 18, and only the molten resin 2 that has flowed to the main-side runner 9 is injected into the cavity 3 via the main gate 4. (Refer to FIG. 4A). Note that the processes according to steps S1 to S3 described above are performed at almost the same timing. Further, in FIGS. 4A and 4B, illustration of the configurations of the injection unit 7 and the delay control unit 13 is omitted for the sake of simplicity.

  As a result, the molten resin 2 injected from the main gate 4 is gradually filled from a region near the main gate 4 (for example, the flow dividing region S) toward a region separated from the main gate 4 (mixing region M). It becomes. At this time, as described above, the cavity 3 is provided with the flow dividing portion 14 that divides the flow of the molten resin 2 into two so as to face the main gate 4. Therefore, the molten resin 2 injected from the main gate 4 and reaching the flow dividing portion 14 is divided into two directions as shown in FIG. 4A, and proceeds so as to fill the dividing flow paths 15a and 15b, respectively. It becomes.

  At this time, it is determined whether or not the elapsed time LT of the timer 21 that has started counting by the injection signal SG has passed a preset time (delay time DT) (step S4). Here, when the elapsed time LT exceeds or is the same as the delay time DT (LT ≧ DT: YES in step S4), the sub injection control means 23 of the delay control unit 13 is controlled to push the push pin of the electromagnetic solenoid 19 18 is controlled to be removed from the sub-runner 10 (step S5: direction of arrow A in FIG. 4A). As a result, the molten resin 2a whose injection is restricted before the push pin 18 of the sub-side runner 10 is pushed out by the pressure from the injection unit 7 and injected from the sub-gate 5 into the cavity 3 (step S6). On the other hand, if the elapsed time LT does not exceed the delay time DT (LT <DT: NO in step S4), the process returns to step S4, and the elapsed time LT is counted again.

  Here, as shown in FIG. 4 (a), the delay time DT is injected from the main gate 4, collides with the flow dividing portion 14, and the molten resin 2 flowing into one of the divided flow paths 15a is divided. It is set to the time immediately before reaching the sub-gate 5. More specifically, when the time required from the start of injection from the main gate 4 to the completion of injection filling of the molten resin 2 into the cavity 3 is set to 0.5 s, the delay time DT is set to 0. It can be 2 s to 0.3 s. Note that the delay time DT needs to be appropriately set according to the size and shape of the cavity 3 and the arrangement of the flow diverter 14.

  At this time, since the molten resin 2a injected from the sub-gate 5 is immediately after being injected from the branch runner 11, it remains in a high temperature state before injection. On the other hand, the molten resin 2 injected from the main gate 4 immediately before reaching the sub-gate 5 gradually loses heat when moving through the cavity 3 and has a lower temperature than when injected from the main gate 4. , Fluidity is decreasing. Therefore, the molten resin 2a newly injected by delaying the injection timing from the sub-gate 5 moves to the mixing region M while being agitated and mixed with the molten resin 2 having lowered fluidity. Thereby, the molten resin 2 is given heat, and the fluidity is restored. As a result, the low-fluidity molten resin 2b that has reached the mixing region M through the other branch channel 15b and the high-fluidity molten resin 2c can be sufficiently mixed and stirred. As a result, the generation of weld lines in the mixed region M is suppressed.

  Thereafter, the elapsed time LT by the timer 21 is counted, and it is determined whether or not a preset filling completion time CT has elapsed (step S7). Here, if the elapsed time LT exceeds or is equal to the filling completion time CT (LT ≧ CT: YES in step S6), the injection stop means 24 of the delay control unit 13 is controlled to melt from the injection unit 7. The injection of the resin 2 is stopped (step S8), the sub injection control means 23 is further controlled, and the push pin 18 of the electromagnetic solenoid 19 is inserted into the sub side runner 10 again (step S9). As a result, the injection of new molten resin 2 into the cavity 3 is stopped. On the other hand, if the elapsed time LT does not exceed the filling completion time CT (LT <CT: NO in step S7), the process returns to step S7, and the elapsed time LT is counted again.

  Thereafter, the molten resin 2 undergoes a phase transition in the cavity 3 and after being sufficiently cooled, the resin molded product is removed from the injection mold 6 and the resin molded product is taken out (step S10). Thereby, the injection molding of the resin molded product is completed. And when producing the said resin molded product in large quantities, by repeating the process of step S1 thru | or step S9 mentioned above, the resin molded product of uniform quality can be produced in large quantities with a short cycle time.

  As described above, according to the injection control device 1 of the present embodiment, after the molten resin 2 is injected into the cavity 3 from the main runner 9 of the branch runner 11 connected to the injection unit 7, the injection timing is set. The molten resin 2 is injected from the sub-side runner 10 into the cavity 3 with a delay. As a result, the heat was gradually taken away by the injection mold 6 which was injected from the main runner 9 and kept at a low temperature, and was newly injected from the sub runner 10 into the molten resin 2 having reduced fluidity. By adding the high-temperature molten resin 2 having high fluidity, the fluidity of the molten resin 2 in the cavity 3 can be improved. Thereby, the stirring and mixing of the molten resin 2 that is diverted and merged again in the mixing region M are performed satisfactorily. As a result, the generation of weld lines in the mixed region M is suppressed.

  Although the present invention has been described based on the preferred embodiments, the present invention is not limited to these embodiments, and various improvements and design changes can be made without departing from the scope of the present invention. It is.

  That is, in the injection control apparatus 1 of the present embodiment, the one using the branch runner 11 in which the main runner 9 and the sub runner 10 are respectively extended from one end of the unit runner 8 is shown, but the present invention is not limited to this. The plurality of sub-runners 10 may be extended from the one end. That is, it is also possible to provide a plurality of sub-side runners according to the complicated cavity shape and delay the injection timing of each. At this time, the delay control unit may control electromagnetic solenoids attached to the respective sub-runners to shift the injection timing for each sub-runner. As a result, when it is difficult for one sub-injection runner to spread a sufficient amount of molten resin into the cavity, the molten resin is injected from each sub-side runner, thereby allowing the molten resin having fluidity to enter the cavity. Can be completely filled to every corner.

It is explanatory drawing which shows schematic structure of the injection control apparatus of this embodiment. It is (a) ladder circuit and (b) electric circuit diagram showing composition of an injection control device. It is a flowchart which shows an example of control by the injection control apparatus. It is explanatory drawing which shows the state of the molten resin at the time of (a) delayed injection by the injection control apparatus, and (b) stirring and mixing. It is explanatory drawing which shows an example of the conventional injection control.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Injection control apparatus 2,2a, 2b, 2c Molten resin 3 Cavity 4 Main gate 5 Sub gate 6 Injection mold 7 Injection unit 8 Unit side runner 9 Main side runner 10 Sub side runner 11 Branch runner 12 Gate opening / closing mechanism part 13 Delay control device 14 Flow diverting section 15a, 15b Dividing flow path 16 Mixing space section 17 Solenoid body 18 Extrusion pin 19 Electromagnetic solenoid 20 Injection operation switch 21 Timer 22 Injection control means 23 Sub injection control means 24 Injection stop means CT Filling completion time DT Delay Time LT Elapsed time F Flow path SG Injection signal S Split flow area M Mixing area

Claims (2)

An injection mold having a main gate and a sub-gate disposed away from the main gate, and injecting molten resin into the cavity from the main gate and the sub-gate;
A unit-side runner connected to an injection unit for injecting the molten resin heated at a high temperature, and a branch formed from one end of the unit-side runner, and a main side runner connected to the main gate and a sub connected to the sub gate A branch runner having a side runner;
A gate opening / closing mechanism provided on the sub-side runner or the sub-gate, for blocking and opening the injection of the molten resin from the sub-gate;
A delay control unit that is connected to the gate opening / closing mechanism and delays the injection of the molten resin from the sub-gate until the molten resin reaches the sub- gate from the start of injection from the main gate;
The cavity is
A flow that is provided at a position that blocks a flow path of the molten resin that faces the main gate, the molten resin collides and the flow is inhibited, and a flow dividing region that diverts the molten resin in at least two directions is formed. A diversion part,
At least two or more flow channels that collide with the flow and flow and the flowed molten resin flows;
And further comprising a mixing space formed with a mixing region in which the molten resin that has been split on the final path side of the branching channel joins again,
The sub-gate is
An injection control device, wherein the injection control device is provided so as to communicate with the cavity in the middle of the one diversion channel connecting the diversion region and the mixing region. The gate opening / closing mechanism is
It is configured using an electromagnetic solenoid formed so that the push pin can be inserted into and removed from the sub-side runner,
The injection control device according to claim 1, wherein the injection of the molten resin from the sub-gate can be adjusted by the extrusion pin.

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