JP2014046589A - Molding die having filling amount adjustment mechanism, and injection molding machine including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a molding die having a filling amount adjustment mechanism that can each independently adjust a resin flow quantity of a resin supplied to two or more molding holes, and an injection molding machine including the molding die.SOLUTION: A runner 49 having a bifurcation runner to flow a molten resin in nest parts 31, 33, 35, 37 is formed in a movable side mold 30 that is used to counter a stationary side mold 60 having a sprue 48, filling amount adjustment mechanism 40, 42, 44, 46 are disposed at each midstream of the bifurcation runner that connects the runner 49 and the nest parts 31, 33, 35, 37, the filling amount adjustment mechanisms 40, 42, 44, 46 include: adjustment runners 41, 43, 45, 47 to adjust a flow quantity of each molten resin, the filling amount adjustment mechanisms 40, 42, 44, 46 revolve by rotary drive force of servo motors M3, M4, M2, M1, change a direction of the adjustment runners 41, 43, 45, 47, and adjust a quantity of a resin inflowing the nest parts 31, 33, 35, 37.

Description

  The present invention relates to an injection molding machine, and more particularly to a molding die having a filling amount adjusting mechanism and an injection molding machine including the molding die.

  When molding is performed using a combination mold of molded products having different filling amounts, it is common to adjust the filling balance by changing the diameter of the runner portion in order to adjust the resin flow rate. However, in this method, depending on the required quantity of molded products having different filling amounts, there may be cases where the molded products are left over and must be stocked or discarded.

  Patent Document 1 discloses a method of adjusting a filling amount by providing a rotation mechanism in a mold. In this method, use a hexagon wrench to adjust manually. Patent Document 2 discloses a core removal method using a through-type servo motor in a slide mold. Further, in Patent Document 3, in a hot runner mold, a rotating element is provided between a nozzle and a molded product, the rotating element is driven by a motor, and a horizontal resin passage is provided above and below the vertical resin passage in the rotating element. A method of alternately connecting the upper and lower sides and filling a molded product with molten resin is disclosed.

JP-A-2-2831212 Japanese Patent Laid-Open No. 4-28516 Japanese Utility Model Publication No. 5-5423

  The method disclosed in Patent Document 1 is manually adjusted using a hexagon wrench. However, since adjustment is performed with the mold open, cycle time loss, mold cooling, and the operator need to enter the mold and make adjustments. Further, a subtle angle shift occurs depending on the tightening condition. Although the method disclosed in Patent Document 2 can adjust the filling amount, the adjustment mechanism must be arranged on the same axis. In addition, the method disclosed in Patent Document 3 always adjusts the filling amount at the top and bottom of the mold, and the supply of resin to individual cavities cannot be adjusted.

  Therefore, in view of the above-described problems of the prior art, the present invention provides a molding die for supplying resin from a gate to a plurality of molding holes via a runner, and a resin flow rate of the resin supplied to the plurality of molding holes, It is an object of the present invention to provide a molding die having a filling amount adjusting mechanism that can be adjusted independently, and to provide an injection molding machine including a molding die having the filling amount adjusting mechanism.

  TECHNICAL FIELD The present invention relates to an injection molding machine, and according to a combination of molded products having different filling amounts, a filling amount adjusting mechanism capable of adjusting a resin flow rate in a runner portion connecting a space (cavity) for pouring resin of a mold and a sprue (sprue). Is provided. The rotation angle of the filling amount adjusting mechanism is adjusted to an optimum rotation angle by the rotation of a servo motor attached to the mold, and the filling amount of the resin into the cavity is adjusted. This is particularly effective in a combination mold of molded products having different filling amounts, but can also be applied to a multi-cavity mold having the same filling amount. The rotation speed of the servo motor is set from the screen of the injection molding machine, for example.

The invention according to claim 1 of the present application is an adjustment that is provided in the middle of the runner in a molding die for supplying resin from the gate to the plurality of molding holes via the runner, and independently adjusts the resin flow rate. A molding die having a filling amount adjusting mechanism comprising a filling amount adjusting mechanism having a runner and a servomotor for driving the filling amount adjusting mechanism.
The invention according to claim 2 includes a positioning pin that rotates around the center of the filling amount adjusting mechanism together with the filling amount adjusting mechanism, and the mold on the side where the filling amount adjusting mechanism is not provided includes the positioning pin. 2. The positioning pin driving mechanism according to claim 1, further comprising: a positioning pin driving mechanism that is provided with a hole into which a positioning pin can be inserted when the filling amount adjusting mechanism is at the rotation angle of the origin, and that moves the positioning pin back and forth in the hole. Is a molding die having a filling amount adjusting mechanism.
According to a third aspect of the present invention, there is provided a filling amount adjusting mechanism having an adjustment runner that is provided in the middle of the runner for supplying resin from a gate to the plurality of molding holes via the runner and independently adjusts the filling amount. An injection molding machine comprising: a molding die provided; a servo motor that drives the filling amount adjusting mechanism; and a control unit that controls the servo motor.

  According to the present invention, in a molding die for supplying resin from a gate to a plurality of molding holes via a runner, the resin flow rate of the resin supplied to the plurality of molding holes can be independently adjusted. A molding die having an amount adjusting mechanism can be provided, and an injection molding machine including a molding die having the filling amount adjusting mechanism can be provided.

It is a block diagram which shows schematic structure of an injection molding machine. It is the figure which looked at the movable side metal mold | die from the nozzle side of the injection cylinder. It is a figure explaining operation | movement of the positioning pin for origin adjustment (at the time of metal mold | die removal). It is a figure explaining being maintained in the state where the positioning pin protruded. It is a figure explaining operation | movement of the positioning pin for origin adjustment, and is a figure explaining a servomotor connection signal being output and a positioning pin returning. It is a figure explaining the state which a positioning pin does not enter in the hole which the positioning pin of the metal mold | die of a fixed side enters. It is a figure explaining rotating a filling amount adjustment mechanism to the angle which a positioning pin enters into the hole in which a positioning pin enters the positioning pin of a fixed side metal mold | die. It is a figure explaining the state which the positioning pin protruded into the hole in which the positioning pin of a fixed side metal mold | die enters. It is a figure explaining the state which opened the movable side metal mold | die and the fixed side metal mold | die in the state in which the positioning pin protruded. It is a figure explaining the state which closed the metal mold | die. It is a flowchart of control which operates the filling amount adjustment mechanism which concerns on this invention. Hereinafter, it demonstrates according to each step.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a schematic configuration of an injection molding machine. FIG. 2 is a view of the mold viewed from the nozzle side. The injection molding machine has an injection part and a mold clamping part on the machine base. The numerical control device 10 of the injection molding machine is a control device that controls the entire injection molding machine, but here, the description will focus on the control of the filling amount of the filling amount adjusting mold. Control other than the control of the filling amount of the filling amount adjusting mold is the same as that of the prior art.

  The numerical controller 10 of the injection molding machine includes a PMCCPU 15 that is a microprocessor for a programmable machine controller, a CNC CPU 18 that is a microprocessor for numerical control, and a servo CPU 12 that is a microprocessor for servo control. By selecting the mutual input / output via this, information can be transmitted between the microprocessors.

  The servo CPU 12 is connected to a ROM 13 that stores a control program dedicated to servo control that executes processing of a position loop, a speed loop, and a current loop, and a RAM 14 that is used for temporary storage of data. Further, the servo CPU 12 is connected to a servo amplifier 11 that drives a servo motor connected to the rotating shaft of the filling amount adjusting mechanism based on a command from the servo CPU 12. The servo motors M1, M2, M3, and M4 (see FIG. 2) are equipped with Menc1, Menc2, Menc3, and Menc4, and signals from the position detectors Menc1, Menc2, Menc3, and Menc4 are fed back to the servo CPU 12. . The rotational positions of the servo motors M1, M2, M3, and M4 are calculated by the servo CPU 12 based on position feedback signals from the position detectors Menc1, Menc2, Menc3, and Menc4, and updated and stored in the current position storage registers. . In FIG. 1, the connection between the servo motor M3 and the servo amplifier 11 and the connection between the position detector Menc3 and the servo CPU 12 are not shown.

  A ROM 16 storing a sequence program for controlling the sequence operation of the injection molding machine and a RAM 17 used for temporary storage of calculation data are connected to the PMC CPU 15, and an automatic operation program for overall control of the injection molding machine is connected to the CNC CPU 18. Are connected to a ROM 19 that stores data and the like, and a RAM 20 that is used for temporary storage of calculation data. The molding data storage RAM 21 formed of a non-volatile memory is a molding data storage memory for storing molding conditions relating to injection molding work, various set values, parameters, macro variables, and the like. The molding data storage RAM 21 stores the rotation angles of the filling amount adjusting mechanisms 40, 42, 44, 46 constituted by the rotation mechanism. The rotation angles of the filling amount adjusting mechanisms 40, 42, 44, 46 can be calculated based on position feedback signals from the position detectors position detectors Menc1, Menc2, Menc3, and Menc4.

  A manual input device with LCD (LCD / MDI) 23 is connected to the bus 24 via the LCD display device 22 and is provided with numeric keys for inputting numeric data and various function keys, and is used to select a graph display screen and a function menu. In addition, various data input operations can be performed. The result of good product discrimination can also be displayed on the display. In the embodiment of the present invention, when the mold is removed, the cutting buttons of the servo motors M1, M2, M3, and M4 are pressed on the operation screen displayed on the LCD / MDI 23. When the servo motor disconnect button is pressed, a servo motor disconnect signal is output to the actuator 55.

  The code | symbol 30 represents the movable side metal mold | die provided with the filling amount adjustment mechanism based on this invention. Servo motors M3, M4, M1, and M2 that rotationally drive the filling amount adjusting mechanisms 40, 42, 44, and 46 are attached to the movable mold 30 by fixing means (not shown).

  As shown in FIG. 2, the movable mold 30 is provided with four nesting portions 31, 33, 35, and 37 on the surface facing the fixed mold 60. Nests 32, 34, 36, and 38 are attached to the respective nesting portions 31, 33, 35, and 37, and molded products having different shapes can be molded in one molding cycle. The number of nesting portions provided in the movable mold 30 is not limited to four. The movable side mold 30 and the fixed side mold 60 correspond to the molding dies in the claims.

  Further, a molten resin injected from a nozzle (not shown) of an injection cylinder provided in the fixed mold 60 is formed on the parting surface of the movable mold 30 facing the parting surface of the fixed mold 60. A runner 49 having a branch runner for pouring the molten resin into the nesting portions 31, 33, 35, and 37 through which the gate 48 for receiving the gas communicates is formed. Filling amount adjusting mechanisms 40, 42, 44, 46 are provided in the middle of the respective branch runners connecting the runner 49 and the nesting portions 31, 33, 35, 37.

  The filling amount adjusting mechanisms 40, 42, 44, and 46 include adjustment runners 41, 43, 45, and 47 for adjusting the flow rate of the molten resin, respectively. The filling amount adjusting mechanism 40 is rotated by the rotational driving force of the servo motor M3 transmitted through the belt 39, and changes the direction of the adjusting runner 41. The filling amount adjusting mechanism 42 is rotated by the rotational driving force of the servo motor M4 transmitted through the belt 39, and changes the direction of the adjusting runner 43. The filling amount adjusting mechanism 44 is rotated by the rotational driving force of the servo motor M2 transmitted through the belt 39, and changes the direction of the adjustment runner 45. The filling amount adjusting mechanism 46 is rotated by the rotational driving force of the servo motor M1 transmitted through the belt 39, and changes the direction of the adjusting runner 47. By changing the direction of the adjustment runner provided in each filling amount adjusting mechanism, the amount of resin flowing in each nesting portion can be adjusted.

  In FIG. 2, the filling amount adjusting mechanism 40 rotates around the central axis in the direction perpendicular to the paper surface. The rotation angle is several tens of degrees at most. The same applies to the other filling amount adjusting mechanisms 42, 44, 46. The filling amount adjusting mechanisms 40, 42, 44, and 46 are each provided with a positioning pin for specifying the origin position of the filling amount adjusting mechanisms 40, 42, 44, and 46. For example, the filling amount adjusting mechanism 42 includes a positioning pin 57 that is driven by the actuator 55. The positioning pins of the other filling amount adjusting mechanisms 40, 44, 46 are not shown.

  Next, positioning of the filling amount adjusting mechanisms 40, 42, 44, 46 will be described. In some cases, the movable mold 30 attached to the movable plate (not shown) of the injection molding machine is removed from the movable plate and attached again for replacement, repair, or inspection of the next production mold.

First, the removal of the mold will be described with reference to FIGS.
FIG. 3 is a diagram for explaining the operation of the positioning pin for adjusting the origin (when the mold is removed). Guide pins 58 are provided on the movable mold 30. The fixed mold 60 is provided with a hole 61 for receiving a guide pin and a hole 62 for receiving a positioning pin. The guide pin 58 is provided for positioning the movable mold 30 and the fixed mold 60, and the guide pin 58 is a hole 61 into which the guide pin provided in the fixed mold 60 is inserted when the mold is closed. Fits in. Although not shown in the figure, the stationary mold 60 is provided with a sprue, and the molten resin injected from the nozzle of the injection cylinder flows to the runner 49 via the sprue. .

  When the mold is removed, the servo motor disconnect button is first selected on the operation screen (the operation screen is displayed on the display device of the LCD / MDI 23). When the servo motor disconnect button is selected, a servo motor disconnect signal is output from the numerical controller 10 to the actuator 55 via the actuator signal line 54. The actuator signal line 54 is connected to the numerical controller 10 when the movable mold 30 is removed, and is removed when the molds (the movable mold 30 and the fixed mold 60) are closed.

  The selection and pressing of the servo motor disconnect button is performed for the purpose of safety of workers such as prevention of electric shock. After the servo motor disconnect button is pressed, the servo motor power line 51 is removed from the power line terminal 53 of the servo motor M4 (see the broken line portion 50). Similarly, the servo motor signal line 52 is removed from the terminal of the position detector Menc4.

  An actuator 55 (air cylinder or hydraulic cylinder) connected to the positioning pin 57 via the connecting member 56 performs forward drive, and the positioning pin protrudes. Even if the actuator signal line 54 of the actuator 55 is cut, the positioning pin 57 is kept in the protruding state because the holding type valve is used (see FIG. 4). Moreover, the connection part of the connection member 56 and the positioning pin 57 is connected by the universal joint. The positioning pins provided in the filling amount adjusting mechanisms 40, 42, 44, 46 are used to adjust the origin of the rotation angle of the filling amount adjusting mechanisms 40, 42, 44, 46. The filling amount adjusting mechanism 40, 42, 44, 46 is a positioning pin (in the case of the filling amount adjusting mechanism 42) unless it is rotated for adjusting the filling amount to the nesting portions 31, 33, 35, 37. The positioning pin 57) enters a hole in which a positioning pin provided in the fixed mold 60 is inserted (the positioning pin 57 enters a hole 62 in which the positioning pin is inserted). The same applies to the filling amount adjusting mechanisms 40, 44, and 46.

Next, description will be made with reference to FIG.
When the mold is attached, the movable mold 30 is attached to a movable board (not shown) with a clamper or the like, the servo motor power line 51 and the servo motor signal line 52 are connected to the servo motor M4, and the actuator signal line 54 is numerically controlled. Connect to the device 10 (see FIG. 3). Thereafter, the servo motor connection button is selected on the operation screen displayed on the display screen of the display device of the LCD / MDI 23. When the servo motor connection button is selected, a servo motor connection signal is output from the numerical controller 10 to the actuator 55 via the actuator signal line 54. Then, the actuator 55 connected to the positioning pin 57 via the connecting member 56 performs the backward drive, and the positioning pin 57 returns.

Here, the case where the filling amount adjusting mechanism rotates to adjust the filling amount, and the positioning pin provided in the movable side mold does not enter the hole in which the positioning pin provided in the fixed side mold enters.
FIG. 6 is a diagram for explaining a state in which the positioning pin does not enter the hole for receiving the positioning pin of the fixed mold. When the filling amount adjusting mechanism 40, 42, 44, 46 is rotated to adjust the resin flow rate, the positioning pin does not enter the hole in which the positioning pin provided in the stationary mold 60 is inserted.

  The rotation center of the positioning pin 57 and the rotation center of the filling amount adjustment mechanism 42 are coaxial, and rotates together with the positioning pin 57 and the filling amount adjustment mechanism 42. In the state shown in FIG. 6, if the positioning pin 57 provided in the filling amount adjusting mechanism 42 is at this angle, the positioning pin 57 does not enter the hole 62 in which the positioning pin provided in the fixed mold 60 is inserted. As shown in FIG. 6B, the positioning pin 57 is misaligned with the hole 62 into which the positioning pin provided in the stationary mold 60 is inserted. For this reason, the positioning pin 57 cannot enter the hole 62 for receiving the positioning pin.

  In FIG. 6B, the portion surrounded by two parallel broken lines is the direction of the adjustment runner 43 when the positioning pin 57 is at the position shown in the figure. The portion surrounded by the two solid lines is the direction of the adjustment runner 43 when the positioning pin 57 is in a positional relationship to enter the hole 62 into which the positioning pin is inserted.

  FIG. 7 is a diagram for explaining that the filling amount adjusting mechanism is rotated to an angle at which the positioning pin enters the hole into which the positioning pin of the fixed mold enters. The positioning pin 57 provided in the filling amount adjusting mechanism 42 rotates the filling amount adjusting mechanism 42 to such an angle that the positioning pin 57 enters the hole 62 in which the positioning in provided in the fixed side mold 60 is inserted. As shown in FIG. 7B, the positioning pin 57 provided in the filling amount adjusting mechanism 42 and the position of the hole 62 into which the positioning pin provided in the fixed side mold 60 enters are aligned. Can enter hole 62 to enter.

  As shown in FIG. 7, the position of the positioning pin of the movable mold is matched with the position of the hole into which the positioning pin of the fixed mold is inserted, and the positioning pin is projected. FIG. 8 is a view for explaining a state in which the positioning pin protrudes into the hole for receiving the positioning pin of the fixed mold. When the positioning pin 57 enters the hole 62 for receiving the positioning pin, the filling amount adjusting mechanism 42 can be positioned. The other filling amount adjusting mechanisms 40, 44, 46 can be similarly positioned.

Then, the mold is opened for exchanging or repairing the mold (the fixed mold 60 or the movable mold 30) to the next production mold. FIG. 9 is a view for explaining a state in which the movable mold and the stationary mold are opened with the positioning pins protruding.
After the mold repair, the fixed mold 60 and the movable mold 30 are closed. FIG. 10 is a diagram illustrating a state in which the mold is closed. As shown in FIG. 7, the positioning pins 57 can enter the holes 62 for receiving the positioning pins provided in the fixed-side mold 60, so that the molds can be matched.

  With the above configuration, first, one molding cycle is executed, the quality of the molded product formed by the nesting portions 31, 33, 35, and 37 is determined, and the molten resin is filled in each nesting portion 31, 33, 35, and 37. Is determined to be inappropriate, the servo motors M3, M4, M2, and M1 are driven to adjust the rotation angles of the filling amount adjusting mechanisms 40, 42, 44, and 46. The determination of a non-defective product may be automatically performed using a known inspection device, and the rotation angle of the filling amount adjusting mechanisms 40, 42, 44, 46 may be automatically adjusted based on the inspection result. The operator may determine whether the molded product is good or not, and the operator may manually input the rotation angles of the servo motors M3, M4, M2, and M1 to instruct them. Further, even during continuous molding, on the operation screen displayed on the LCD / MDI 23, it is possible to change the rotation angle of the filling amount adjusting mechanisms 40, 42, 44, 46, and there is no need to stop the molding operation.

  Then, the PMC CPU 15 controls the sequence operation of the entire injection molding machine, and the CNC CPU 18 distributes the movement command to the servo motors of the respective axes based on the operating program of the ROM 19 and the molding conditions stored in the molding data storage RAM 21. Do. Servo CPU (not shown) controls position loop control and speed loop based on movement command distributed to each axis and position and speed feedback signal detected by position / speed detector provided on each axis. Control, further servo control such as current loop control is performed, so-called digital servo processing is executed, servo motors for each axis are controlled, and a molding cycle is executed.

FIG. 11 is a control flowchart for operating the filling amount adjusting mechanism according to the present invention. Hereinafter, it demonstrates according to each step.
[Step SA01] A molding cycle (one cycle) is executed.
[Step SA02] It is determined whether or not the rotation angle of the filling amount adjusting mechanism is being adjusted. If the adjustment is in progress (YES), the process returns to Step SA01. If the adjustment is not in progress (NO), the process proceeds to Step SA03. .
[Step SA03] Continuous molding is executed.
[Step SA04] It is determined whether or not the continuous molding is completed. If the continuous molding is completed (YES), the process proceeds to Step SA05. If the continuous molding is not completed (NO), the process returns to Step SA03.
[Step SA05] The rotation angle of the filling amount adjusting mechanism is saved in the mold file stored in the storage device of the injection molding machine, and the process is terminated.

Step SA02 (procedure for determining the flow rate of the filling amount adjusting mechanism) in the flowchart will be supplementarily described.
The procedure for determining the flow rate of the filling amount adjusting mechanism includes the following.
(1) Maximize the flow rate of the filling amount adjusting mechanism of all the cavities (nesting parts).
(2) Perform molding and compare the filling amount of each cavity.
(3) The flow rate of the filling amount adjustment mechanism for the cavity with the smallest filling amount is kept at the maximum, and the flow rate for the cavity with the smallest filling amount is determined. (Hereinafter, the cavity whose flow rate has been determined is referred to as a flow rate determined cavity, and the cavity whose flow rate has not been determined is referred to as a flow rate undetermined cavity.)
(4) A cavity other than the cavity with the smallest filling amount in (3) is set as a flow rate undetermined cavity.
(5) The flow rate of the filling amount adjustment mechanism of the undetermined flow rate cavity is reduced by a predetermined amount.
(6) Molding is performed, and the filling amount of each cavity is compared.
(7) If there is a cavity having a filling amount equivalent to the cavity whose flow rate has been determined in the cavity whose flow rate has not been determined, the cavity is determined as the flow rate of the filling amount adjusting mechanism for that cavity, and that cavity is set as the flow rate-determined cavity.
(8) Repeat steps (5) to (7) until there are no undetermined cavities.

  However, although each procedure may be performed by an operator, each procedure can be automatically performed by measuring the filling amount of each cavity with a weight measuring device or a camera. It is also possible to adjust the flow rate of the filling amount adjusting mechanism of each cavity from the weight ratio of the molded product and the injection volume ratio, start molding, and reduce the number of flow determination procedures of the filling mechanism.

  According to the present invention, by using a combination mold of molded products with different filling amounts, the rotation mechanism (filling amount adjustment mechanism) of the runner part is driven by a servo motor, making it easy to set a fine angle and filling during good product molding. The rotation angle of the quantity adjusting mechanism can also be stored in the mold file, and there is no need to manually set the angle when the mold is mounted. Since the rotation angle can be changed on the screen even during continuous molding, there is no need to stop the molding operation. Further, there is no need for an operator to enter the mold and adjust the rotation angle manually.

  If the combination of molded products is determined once, for example, a four-piece mold may be rotated at the value of the rotation angle even if the nesting location changes. This is particularly effective in a combination mold of molded products having different filling amounts, but can also be applied to a multi-cavity mold having the same filling amount.

M1 Servo motor M2 Servo motor M3 Servo motor M4 Servo motor Menc1 Position detector Menc2 Position detector Menc3 Position detector Menc4 Position detector

10 Numerical controller 11 Servo amplifier 12 Servo CPU
13 ROM
14 RAM
15 PMCCPU
16 ROM
17 RAM
18 CNCCPU
19 ROM
20 RAM
21 Molding data storage RAM
22 LCD display device 23 LCD / MDI
24 buses

DESCRIPTION OF SYMBOLS 30 Movable side metal mold 31 Nesting part 32 Nesting 33 Nesting part 34 Nesting 35 Nesting part 36 Nesting part 37 Nesting part 38 Nesting 39 Belt 40 Filling amount adjusting mechanism 41 Adjusting runner 42 Filling amount adjusting mechanism 43 Adjusting runner 44 Filling amount adjusting mechanism 45 Adjusting runner 46 Filling amount adjusting mechanism 47 Adjusting runner 48 Spout 49 Runner

51 Servo motor power line 52 Servo motor signal line 53 Power line terminal 54 Actuator signal line 55 Actuator 56 Connecting member 57 Positioning pin 58 Guide pin

60 Fixed side mold 61 Hole for guide pin 62 Hole for positioning pin

Claims (3)

In a molding die that supplies resin from a gate to a plurality of molding holes via a runner,
A filling amount adjusting mechanism provided in the middle of the runner and having an adjusting runner for independently adjusting the resin flow rate;
A servo motor for driving the filling amount adjusting mechanism;
A molding die having a filling amount adjusting mechanism. A positioning pin that rotates around the center of the filling amount adjusting mechanism together with the filling amount adjusting mechanism;
The mold on the side where the filling amount adjusting mechanism is not provided is provided with a hole into which a positioning pin can be inserted when the filling amount adjusting mechanism is at the rotation angle of the origin. The molding die having a filling amount adjusting mechanism according to claim 1, further comprising a positioning pin driving mechanism that advances the positioning pin. A molding die provided with a filling amount adjustment mechanism having an adjustment runner that is provided in the middle of the runner for supplying resin from the gate to the plurality of molding holes via the runner, and independently adjusts the filling amount;
A servo motor for driving the filling amount adjusting mechanism;
A control unit for controlling the servo motor;
An injection molding machine characterized by comprising:

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