JPH11156908A - Injection mold and production of injection molded product - Google Patents

Abstract

PROBLEM TO BE SOLVED: To heat the surface of a cavity within a short time in a mold closed state and to provide an injection molded product excellent in appearance quality by a mold low in cost. SOLUTION: High temp. air is supplied into a cavity 5 from a high temp. air generator 30 through a suction port 19 in a mold closed state and discharged from an exhaust port 20 to heat the surface of the cavity 5 to a definite temp. Valve bodies 15, 16 are slid by actuators 17, 18 to close the suction port 19, the exhaust port 20 and the opening part of the cavity 5. A molten resin is charged in the cavity to be dwelled and cooled to take out a molded product.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mold for injection molding and a method for producing an injection-molded product for improving the appearance quality by uniformly increasing the surface temperature of a cavity.

[0002]

2. Description of the Related Art As a method of injection molding a thermoplastic resin, a mold comprising a fixed mold and a movable mold in which a cavity is formed in a closed state is used. In general, a resin is injected and filled, and after the resin is cooled and solidified, the mold is opened to take out the molded product to the outside of the mold. In such an injection molding method, when the surface temperature of the cavity at the time of filling the molten resin is low, rapid cooling and solidification starts from a portion where the injected molten resin touches the cavity surface, thereby increasing the viscosity of the resin. Flow resistance increases.

[0003] As a result, poor appearance of a molded product such as a weld line, a flow mark or a silver streak occurs. In addition, if the temperature of the cavity surface is low at the time of filling the resin, there is a problem that it is difficult to obtain a molded product having a smooth surface appearance due to the floating of the filler in the resin containing the filler. On the other hand, by raising the surface temperature of the cavity, it becomes possible to perform the filling of the molten resin in the cavity by low-pressure injection, thereby eliminating the above-mentioned poor appearance of the molded product, and also transferring the molded product at the time of shaping. A glossy molded product having excellent properties can be obtained.

[0004]

However, when the surface temperature of the cavity is raised to a high temperature, it takes a long time until the molded product is cooled to a temperature at which the molded product can be taken out, resulting in poor productivity. Therefore, it is ideal that the surface temperature of the cavity is high when the molten resin is filled, and the surface temperature of the cavity rapidly decreases after the completion of the filling. Various techniques have been proposed to achieve this. For example, Japanese Patent Application Laid-Open No. H8-24407
No. 2 and Japanese Patent Application Laid-Open No. 9-109214, there is a heating method using high-temperature air, which can be applied even if the cavity shape is complicated. This is a desirable method for heating the cavity because the cavity can be heated in a long time.

[0005] However, this heating method has a drawback that the mold manufacturing cost is increased because a mold mating surface that slides in the mold opening and closing direction is provided. Also, if the injection molding machine does not have a function to suspend the closing of the mold immediately before the completion of the closing of the fixed mold and the movable mold and to allow high-temperature air to flow, the mold closing control circuit must be modified. There was also a disadvantage that it did not. Therefore, an object of the present invention is to provide an injection molding die and a method of manufacturing an injection molded product, which are capable of molding a molded product having excellent appearance quality in view of the above-mentioned drawbacks.

[0006]

According to the first aspect of the present invention,
A cavity formed by closing the mold between a fixed mold consisting of a fixed mold plate and a cavity block, and a movable mold consisting of a movable mold plate and a core block, the air supply and exhaust holes connected to the high-temperature air generator. And a valve body connected to an actuator and slidable by reciprocating operation of the actuator is provided in a mold so as to open and close the air supply hole and the air exhaust hole. It is a mold.

According to a second aspect of the present invention, in a state where the fixed mold and the movable mold are closed, high-temperature air is supplied from the high-temperature air generator into the cavity through the air supply hole, and the high-temperature air is discharged from the exhaust hole. After heating the cavity surface to a predetermined temperature, the valve body connected to the actuator, and provided in the mold so that the air supply hole and the exhaust hole can be opened and closed, is slid by the reciprocating operation of the actuator, A method for producing an injection-molded article, comprising closing an air supply hole and the exhaust hole, and then filling a molten resin.

(Function) The cavity is heated from the vicinity of the air supply port by the ventilation of high-temperature air, and the cavity surface is heated to a predetermined temperature in a short time by the ventilation of a large amount of air. The resin injected into the cavity is filled while maintaining fluidity to the end of the cavity whose surface is heated by the hot air. Therefore, appearance defects are less likely to occur.

The heat transfer coefficient between the cavity surface and the high-temperature air is V ^0.5 if the flow velocity of the high-temperature air in the cavity is V.
Proportional to ~V ^0.8, proportional cavity spacing (corresponding to the thickness of the molded article) in t ^-0.5 ~t ^-0.2 if the t. In other words, the higher the flow rate of hot air in the cavity,
The smaller the cavity spacing, the higher the heat transfer coefficient. Therefore, the space between the cavities is narrower than in the state immediately before completion of the conventional mold closing, and a large amount of high-temperature air can be sent into the closed cavity in the mold closed state, so that the heat transfer coefficient becomes extremely large.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a cross-sectional view showing an example of an injection mold according to the present invention, showing a state before the mold is closed and before the molten resin is filled. The fixed mold 1 includes a fixed mold plate 3, a cavity block 6, a heat insulating plate 8, a locate ring 11, and a sprue bush 12, and the movable mold 2 includes a movable mold plate 4, a core block 7, and a heat insulating plate 9. The cavity block 6 and the core block 7 are fitted and fixed to the fixed mold plate 3 and the movable mold plate 4, respectively. Cooling holes 13 and cooling holes 14 are provided inside the cavity block 6 and the core block 7, respectively.

Cavity block 6 and core block 7
It is desirable that the material has a low thermal conductivity. By using such a material, the cavity surface can be mainly heated. The temperature of the cavity surface can be raised to a required temperature in a short time. For example, SUS630 or SUS420 which is about half or less of the thermal conductivity of high carbon steel is preferable. The heating temperature of the cavity block 6 and the core block 7 is desirably equal to or higher than the glass transition temperature of the resin from the viewpoint of the quality of the molded product. Because of the influence, it is preferable to determine the quality and productivity for each type of resin used in consideration of the quality and productivity.

The space between the fixed mold plate 3 and the cavity block 6 is insulated by the air insulation layer 10 and the heat insulation plate 8, and the space between the core block 7 and the movable mold plate 4 is insulated by the heat insulation plate 9. By providing these members, the heating range by the high-temperature air is limited to the cavity block 6 and the core block 7, and the amount of heat required for heating can be saved. Also, by making the cavity block 6 and the core block 7 thin, the cavity block 6 and the core block 7 are made thin.
Can be quickly raised or cooled to the required temperature.

Valve bodies 15 and 16 are in contact between the lower surface of the fixed mold 1 and the upper surface of the movable mold plate 4, and the actuator 1
It is attached to the tip of 7,18. Note that, for example, a hydraulic cylinder or a pneumatic cylinder can be used as the actuator. The valve bodies 15, 16 are actuators 17, 1
By the drive of the movable member 8, the movable member 4 can reciprocate back and forth along a sliding groove (not shown) on the upper surface of the movable mold plate 4.
The sliding groove (not shown) may be provided on the lower surface of the fixed die 1.

The movable mold plate 4 has an air supply hole 19, which is a supply path for supplying high-temperature air from outside the mold to the cavity 5. The movable mold plate 4 has an exhaust hole 20 and a cavity 5.
This is a discharge path for discharging hot air from the mold to the outside of the mold. In addition, since the air supply hole 19 and the exhaust hole 20 have a structure communicating with each other in the cavity 5, an air flow path having a large cross-sectional area can be secured, and a large amount of high-temperature air can be supplied at high pressure.

An air supply port 21 and an exhaust port 22 communicate between the air supply port 19 and the exhaust port 20 and the cavity 5, and the air supply port 21 and the exhaust port 22 are opened and closed by valve bodies 15 and 16.
At the same time when the valve bodies 15 and 16 close the air supply port 21 and the exhaust port 22, the opening of the cavity 5 opened to the air supply port 21 and the exhaust port 22 is also closed, and the valve bodies 15 and 16 are closed. The cavity 5 thus formed forms a mold of a molded product. In FIG. 1, one air supply hole 19 and one air exhaust hole 20 are provided, and one valve element is provided in accordance with the air supply hole 19 and the air exhaust hole 20. However, the size and shape of the cavity and the flow of high-temperature air in the cavity are taken into consideration. It is desirable to determine the number of air supply holes, exhaust holes, and valve bodies and their installation positions.

The high-temperature air generator 30 is connected to the air supply hole 19 by a heat-resistant hose 27. Hot air generator 3
As 0, any device having an air heating device such as a heater and a blower capable of supplying high-temperature air into the mold may be used.
However, since it is necessary to supply a large amount of high-temperature air in a short time, it is necessary to use a high-temperature air generator using a heater having a hot start function capable of instantaneously supplying high-temperature air at the same time as starting to blow air into the cavity 5. Is desirable.

The hot air generator 30 having a hot start function has a heater 26, a blower 23, a safety valve 24, and a switching valve 25 built therein. By having a hot start function capable of supplying hot air instantaneously, hot air can be supplied to the cavity 5 instantaneously. Normally, it is desirable for the blower 23 to be operated continuously, because of its structure.
After passing through the hose 29 by 5, the air may be released to the atmosphere or returned to the blower 23 and recycled.

The high-temperature air has a temperature of 250 ° C. to 450 ° C.
C., pressure is preferably in the range of 0.3 to 1.0 kg / cm ² , and the temperature and pressure are determined in consideration of the size and shape of the cavity, the flow of high-temperature air in the cavity, and the resin used. It is desirable to select from within this range. When the high-temperature air is reused, each part of the high-temperature air heating device 30 is made to have heat resistance. The intermittent operation of the heater 26 is desirable from the viewpoint of thermal efficiency. However, it is preferable to always preheat so that high-temperature air can be sent to the cavity 5 simultaneously with the start of air supply, and a heater having a hot start function is desirable. The high-temperature air discharged from the exhaust hole 20 may be discharged to the atmosphere via the heat-resistant hose 28 or may be recirculated to the high-temperature air generator 30. The temperature of the discharged high-temperature air is about 100 to 200 ° C., and it can be said that there is no problem even if it is released to the atmosphere.

Next, a method for manufacturing an injection-molded article using the mold of the present invention will be described with reference to FIGS.
Before closing the injection mold, the actuators 17, 1
8, the valve bodies 15 and 16 are retracted to open the air supply port 21 and the exhaust port 22. The valve bodies 15 and 16 may be retracted at any time from the mold opening step to the start of filling of the resin after the mold closing is completed. Upon receiving a signal from the limit switches (not shown) attached to the actuators 17 and 18 indicating that the valve bodies 15 and 16 have been retracted, the switching valve 25 is switched to send air from the blower 23 to the heater 26, and the heat-resistant hose 27 and Hot air is supplied to the narrow space of the cavity 5 through the pores 19 and the air supply port 21 to flow at a high speed and heat the surface of the cavity 5.

After the surface of the cavity 5 is heated for a predetermined time, or when a thermocouple thermometer (not shown) provided near the surface of the cavity 5 reaches a predetermined temperature, the switching valve 25 is switched to switch the high temperature to the cavity 5. Interrupt the air supply. At the same time, the actuators 17 and 18 are operated to advance the valve bodies 15 and 16 so that the air supply port 21 and the exhaust port 22
Is closed. FIG. 2 shows this state. In this state, the opening of the cavity 5 is closed by the tips of the valve bodies 15 and 16, and the resin does not leak from the cavity 5 in the subsequent injection of the molten resin into the mold. After completion of the injection step, cooling, opening of the mold, and removal of the mold are performed to complete one cycle of molding, and the mold closing step of the next cycle is started.

After the molten resin is injected into the cavity 5,
Cooling holes 13 in cavity block 6 and core block 7,
The cooling medium may be circulated through the cooling medium 14 only from the completion of filling of the molten resin to the start or the end of removal of the molded product. During the heating of the surface of the cavity 5 with the high-temperature air, the surface temperature of the cavity 5 can be heated more quickly and effectively by interrupting the flow of the cooling medium.

[0022]

According to the injection molding die of the present invention, it is only necessary to provide the valve element and the actuator as compared with the case where the die mating surface is slid in the die opening and closing direction. Production costs can be reduced. Also,
Since the high-temperature air is supplied in the closed state of the mold, the air can flow in the very narrow cavity interval, and the heat transfer coefficient between the high-temperature air and the cavity surface can be increased. Further, since both the cavity block and the core block can be heated simultaneously by the high-temperature air, the deformation of the molded product due to the difference in temperature can be prevented.

Therefore, the temperature of the cavity surface can be raised to a desired temperature in a short time, and the heat of the high-temperature air can be effectively transmitted to the cavity surface. In addition, heating by high-temperature air can be applied to any mold, so it can be easily applied to molds with complicated shapes, and large and thin-walled molding can be easily performed with relatively low injection pressure. it can.

In the method for manufacturing an injection-molded article according to the second aspect of the present invention, the solidification of the molten resin in the cavity is delayed,
The following effects can be expected by facilitating the flow. 1) Improvement of transferability and improvement of appearance quality of molded products. 2) Large and thin molded products can be molded. 3) Low pressure molding is possible. 4) Poor molding—elimination of weld lines, flow marks, silver streaks, and floating of reinforcements. In addition, since the surface of the cavity is heated with high-temperature air while the mold is closed, a large volume of high-temperature air can be supplied, the wind speed can be increased, and the heat transfer coefficient can be increased. And can be uniformly heated to every corner.

Further, the present invention is applicable regardless of the presence or absence of a function of interrupting the mold closing step of the injection molding machine to temporarily stop the mold closing step and allow high-temperature air to flow immediately before the completion of the closing of the fixed mold and the movable mold. Can be implemented.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a structure of an injection mold according to the present invention in a closed state.

FIG. 2 is a cross-sectional view showing a structure of an injection mold in a state where a passage of high-temperature air is blocked.

[Explanation of symbols]

 Reference Signs List 1 fixed mold 2 movable mold 3 fixed mold plate 4 movable mold plate 5 cavity 6 cavity block 7 core block 8, 9 heat insulating plate 10 air heat insulating layer 13, 14 cooling hole 15, 16 valve body 17, 18 actuator 19 air supply hole Reference Signs List 20 exhaust hole 21 air supply port 22 exhaust port 23 blower 24 safety valve 25 switching valve 26 heater 30 high-temperature air generator

Claims (2)

[Claims] An air supply hole and an exhaust hole connected to a high-temperature air generator are closed between a fixed mold composed of a fixed mold plate and a cavity block and a movable mold composed of a movable mold plate and a core block. A valve body connected to an actuator and slidable by reciprocating operation of the actuator is provided in a mold so as to open and close the air supply hole and the air exhaust hole. Mold for injection molding. 2. A high-temperature air generator supplies high-temperature air into a cavity through an air supply hole in a state in which a fixed mold and a movable mold are closed, and discharges the high-temperature air from an exhaust hole to form a predetermined surface of the cavity. After heating to a temperature, a valve body connected to an actuator and provided in a mold so as to open and close the air supply hole and the air exhaust hole is slid by the reciprocating operation of the actuator, and the air supply hole and the exhaust A method for producing an injection-molded article, comprising closing a hole and then filling a molten resin.