CN215151409U

CN215151409U - Injection-molded article and molding apparatus

Info

Publication number: CN215151409U
Application number: CN202120280305.8U
Authority: CN
Inventors: 八木孝将; 小菅守
Original assignee: Koito Manufacturing Co Ltd
Current assignee: Koito Manufacturing Co Ltd
Priority date: 2020-02-08
Filing date: 2021-02-01
Publication date: 2021-12-14
Anticipated expiration: 2031-02-01
Also published as: JP7458809B2; JP2021123081A; CN113246398A; CN113246398B

Abstract

The utility model provides a prevent injection molding piece forming device of high-quality that weld line produced. The injection molded article is a molded article (lens) (2) molded into a shape elongated in at least one direction, a plurality of gate marks (24) are present in the lens (2) along the longitudinal direction thereof, and the cross-sectional area of a first gate mark (24(G1)) present at the center of the injection molded article in the longitudinal direction is larger than the cross-sectional area of second gate marks (24(G2)) present at both sides thereof. Further, a third gate mark (24(G3)) may be present on the outer side in the longitudinal direction of the second gate mark (24(G2)), and the cross-sectional area of the third gate mark (24(G3)) may be larger than the cross-sectional area of the second gate mark (24 (G2)).

Description

Injection-molded article and molding apparatus

Technical Field

The present invention relates to an injection-molded article formed by injection molding and a molding apparatus for injection-molding the injection-molded article.

Background

A method for manufacturing a resin molded article such as a lens having translucency, which is one of the components of an automobile lamp, uses an injection molding method in which a transparent resin is injected into a cavity formed in a mold. When a long resin molded article is molded by such an injection molding method, so-called sequential molding may be employed for the purpose of improving molding quality. The sequential molding is a molding method as follows: a plurality of gates are arranged in a cavity of a mold, resin is injected from the gates, and timing of injection of the resin from the gates is varied in time in order to prevent weld lines generated by collision of the resin injected from the gates in the cavity.

In patent document 1, in order to adjust the resin injection timing of the gate in the sequential molding, the timing of resin injection is controlled as follows: a sensor for detecting the injected resin is disposed in the mold, the timing at which the resin injected from the first gate reaches the second gate is detected, and the injection of the resin from the second gate is started at the detected timing. Patent document 2 proposes a technique for suitably molding a molded article having an opening by multi-gate molding (sequential molding).

Documents of the prior art

Patent document

Patent document 1: japanese laid-open patent publication No. 2015-47858

Patent document 2: japanese patent No. 5751043

SUMMERY OF THE UTILITY MODEL

Problem to be solved by the utility model

The designer of the present invention, when studying sequential molding, has found that the weld line cannot be completely prevented according to the shape of the molded article. When the reason for this was further examined, it was found that the temperature of the resin injected from the first gate decreased when it reached the second gate, and a temperature difference was generated between the resin injected from the second gate and the resin newly injected from the second gate, and that a weld line was generated at an interface where the resins having different temperatures collided.

As a recent automotive lamp, a tail lamp having a length of 1m or more, which is extended over substantially the entire length of the vehicle body width, has been proposed, and it is required to resin-mold a lens and a front surface cover thereof. When such a resin molded article is sequentially molded, it is preferable to provide as many gates as possible, but as the number of gates increases, it is difficult to control the timing of sequential molding, and as a result, the probability of weld line generation increases. Further, if the number of gates is increased, the number of steps for removing gate pieces remaining in a molded article after molding is increased, which causes an increase in manufacturing cost.

An object of the utility model is to provide a prevent high-quality injection forming part of weld line production. In addition, the present invention provides a molding method and a molding apparatus for molding a high-quality injection molded article.

Means for solving the problems

The utility model relates to a forming part, it takes shape to be at least in the longer shape of one side, in this forming part, exists a plurality of runner marks along its length direction, and the sectional area that exists in the first runner mark of length direction central authorities of injection forming part is bigger than the sectional area that exists in the second runner mark of first runner mark both sides. In the present invention, a third gate mark may be present outside the second gate mark in the longitudinal direction, and the cross-sectional area of the third gate mark may be larger than the cross-sectional area of the second gate mark.

The present invention provides a molding apparatus having a cavity formed in a shape that is long in at least one direction, a plurality of gates being provided along a length direction of the cavity, and resin being injected into the cavity from the plurality of gates, the gates comprising: a first gate which is arranged at a position close to the center of the cavity in the length direction and has a required opening area; and a second gate disposed on both sides of the first gate and having an opening area smaller than that of the first gate. In the present invention, a third gate is disposed outside the second gate in the longitudinal direction, and the opening area of the third gate is set to an area proportional to the flow length of the resin injected from the third gate.

Effect of the utility model

According to the present invention, by appropriately setting the opening areas of the first gate and the second gate, it is possible to suppress the occurrence of weld lines in the sequential molding and to form a high-quality injection molded article, and to facilitate timing control in the sequential molding. Further, the step of removing the gate piece after molding can be reduced.

Drawings

Fig. 1 is a rear view of an automobile equipped with a tail lamp to which the injection molded article of the present invention is applied.

Fig. 2 is an external view of the tail lamp of fig. 1.

Fig. 3 is a sectional view taken along the line III-III of fig. 2.

Fig. 4 is an enlarged perspective view of a part of the lens.

Fig. 5 is a schematic plan view of a molding die with a part broken away.

Fig. 6 is an enlarged sectional view taken along line VI-VI of fig. 5.

Fig. 7A is a sectional view and a schematic perspective view illustrating a first gate and a gate piece.

Fig. 7B is a sectional view and a schematic perspective view illustrating the second gate and the gate piece.

Fig. 8 is a diagram illustrating a gate structure in a molding apparatus for

molding lenses

1, 2, and 3 having different shapes.

Fig. 9 is a schematic diagram illustrating the flow of resin during molding.

Description of the reference numerals

1: a main body; 2: a lens; 3: a lamp housing; 4: a light source unit; 21: a front face portion; 22: a peripheral wall portion; 23: a leg portion; 24(G1 to G3): gate mark; 25(G1 to G3): a gate piece; 100: a forming device; 101: a lower die; 102: an upper die; 103: a cavity; 104(G1 to G3): a gate; 105: a pouring channel; 106: a throttle section; TL: and a tail light.

Detailed Description

Next, embodiments of the present invention will be described with reference to the drawings. Fig. 1 is a rear view of an automobile CAR equipped with a tail light TL provided with a lens as an injection-molded article of the present invention. In the rear part of the CAR body of the CAR, a tail lamp TL having a length of 1m or more, and here about 1.5m, is arranged in the horizontal direction over substantially the entire length in the vehicle width direction. The tail light TL also functions as a stop light. The tail lamp TL is formed in a shape in which the vertical width of the left and right end portions is increased in a tapered manner in order to obtain an appearance effect. In the present embodiment, the turn signal lamp TSL and the backup lamp BUL are disposed separately below both left and right end portions of the tail lamp TL.

Fig. 2 is a schematic external view of the tail lamp TL, and fig. 3 is a cross-sectional view taken along line III-III of fig. 2. The tail lamp TL includes a groove-shaped body 1 elongated in the left-right direction and an elongated lens 2 integrally attached to an opening of the body 1, and the body 1 and the lens 2 constitute a lamp housing 3. The lens 2 is an injection-molded article of the present invention, and is molded from a light-transmitting red resin.

A light source unit 4 is disposed in the lamp housing 3. The light source unit 4 includes a substrate 41 fixedly supported by the main body 1, and a light source mounted on the front surface of the substrate 41, and the light source here is an LED (light emitting element) 42 emitting white light or red light. Although not shown in the drawings, a plurality of LEDs 42 are mounted on the substrate 41 in a state where they are arranged along the longitudinal direction of the tail light TL. The light emission of each LED42 is controlled by a light emitting circuit, not shown, and emits light at a relatively low luminance when functioning as a tail light and emits light at a relatively high luminance when functioning as a stop light.

Fig. 4 is an enlarged perspective view of a part of the lens 2. The lens 2 is configured to include: a front portion 21 that forms the front shape of the tail lamp in a shape corresponding to the opening of the main body 1; a wall-shaped peripheral wall portion 22 formed along the periphery of the front portion 21; and a leg portion 23 protruding outward from the peripheral wall portion 22.

As shown in fig. 1 and 2, the front surface portion 21 has an elongated shape with an extremely small width dimension with respect to the longitudinal dimension, and both ends in the longitudinal direction thereof are formed in a tapered shape with the width dimension gradually increasing toward both ends. In the present embodiment, the front surface portion 21 is formed in a shape slightly curved in the vertical direction and the lateral direction in conformity with the curved surface shape of the rear portion of the vehicle body of the CAR.

The leg portion 23 is bonded or welded to the peripheral edge portion 11 of the main body 1, thereby integrating the main body 1 and the lens 2. In the leg portion 23, a plurality of gate marks, here five gate marks 24, are present at a desired interval in the longitudinal direction of the lens 2 on one side surface in the width direction of the lens 2, here the side surface facing the lower side in fig. 2.

The gate mark 24 is present as one first gate mark 24(G1) disposed at the center in the longitudinal direction of the lens 2, two second gate marks 24(G2) disposed so as to sandwich the first gate mark 24(G1) in the longitudinal direction, and two third gate marks 24(G3) further disposed at the outer sides in the longitudinal direction of each of the second gate marks 24 (G2). As described later, the gate mark 24 is formed by cutting and removing a gate piece formed by a gate for injecting resin into the cavity when the lens 2 is molded, after molding.

As shown in fig. 4, the cross-sectional shape of the gate mark 24, that is, the shape of the cut surface is a trapezoid with the thickness direction of the leg portion 23 of the lens 2 being the vertical direction. The cross-sectional area of the first gate mark 24(G1) is larger than the cross-sectional area of the second gate mark 24(G2), and particularly the vertical thickness dimension of the first gate mark 24(G1) is larger than the thickness dimension of the second gate mark 24 (G2). The cross-sectional area and thickness dimension of the third gate mark 24(G3) are appropriately set according to the shape of the lens 2, and here are formed to be larger than the cross-sectional area and thickness dimension of the second gate mark 24(G2) and equal to or slightly smaller than the cross-sectional area and thickness dimension of the first gate mark 24 (G1).

Fig. 5 is a schematic plan view, partially broken away, illustrating a conceptual structure of a mold of the injection molding apparatus 100 for injection molding the lens 2. Fig. 6 is an enlarged sectional view taken along line VI-VI of fig. 5. The injection molding apparatus 100 includes a pair of a lower mold 101 and an upper mold 102, and an elongated cavity 103 corresponding to the lens 2 is formed in a parting surface where the lower mold 101 and the upper mold 102 are in contact with each other. In the lower mold, five gates 104 connected to the cavity are formed. The five gates 104 are arranged at a desired interval along the longitudinal direction of the cavity 103, communicate with a resin injection portion not shown through runners 105, and can inject resin into the cavity 103 at independent timings.

Hereinafter, the five gates 104 are referred to as a single first gate 104(G1) disposed at the center in the longitudinal direction of the cavity 103, two second gates 104(G2) disposed on both sides sandwiching the first gate 104(G1) in the longitudinal direction, and two third gates 104(G3) disposed further outside the second gates 104 (G2). In addition, only the first gate G1, the second gate G2, and the third gate G3 may be described below.

In the injection molding apparatus 100, sequential molding is performed in a state where the parting surfaces of the lower mold 101 and the upper mold 102 are brought into contact with each other to form the cavity 103. Since the sequential molding is a conventional technique as described above, detailed description is omitted, and the resin is injected into the cavity 103 from the first gate G1, the resin is injected from each of the two second gates G2 after a predetermined time, and the resin is injected from each of the two third gates G3 after a predetermined time. By performing this sequential molding, it is possible to suppress or prevent the occurrence of weld lines in the resin injected into the cavity 103 from each of the first gate G1 to the third gate G3, and to mold a high-quality lens.

After the resin injected into the cavity 103 is cured, the lower mold 101 and the upper mold 102 are separated, and the molded lens 2 is released from the cavity 103. In the molded lens, as shown by the broken lines in fig. 4, since gate pieces (piece portions molded by the gates) 25(G1, G2, G3) are formed at positions corresponding to the gates from the first gate G1 to the third gate G3, respectively, the gate pieces 25 are cut and removed by the gate cutting step. The gate mark 24 is formed at a portion where the gate piece 25 is removed (G1 to G3).

Fig. 7A is a diagram illustrating the first gate G1, and fig. 7B is a diagram illustrating the second gate G2. In each figure, (a) is a sectional view similar to fig. 6, and (b) is a sectional view in a direction perpendicular thereto. As shown in fig. 7A and 7B, the first gate G1 and the second gate G2 have the same opening shape as an inverted trapezoid, and the tapered shape of both sides of the trapezoid ensures the draft when the lens 2 existing on the lower mold 101 is released upward after the lens 2 is molded.

As shown in (a) and (b) of fig. 7A, the height and the upper and lower sides of the inverted trapezoid of the first gate G1 are set to desired dimensions so as to form a desired opening area. The required opening area is set to an area such that the resin injected from the first gate G1 flows in the longitudinal direction in the cavity 103 and the flow front end of the resin can reach the second gate G2 within a predetermined time. The predetermined time is a time during which the resin reaching the second gate G2 does not drop below a predetermined temperature.

As shown in (a) and (B) of fig. 7B, the height and the top and bottom dimensions of the trapezoidal opening of the second gate G2 are smaller than those of the first gate G1, and thus the opening area of the second gate G2 is formed smaller than that of the first gate G1. The opening area of the second gate G2 is set to an opening area capable of injecting resin in an amount such that the temperature of the resin injected from the second gate G2 does not decrease to a predetermined temperature when the resin flows to the third gate G3 in the cavity 103.

In the present embodiment, in the second gate G2, a throttle portion 106 having a tapered cross-sectional shape is formed in each of the lower die 101 and the upper die 102. The throttle portion 106 is formed to protrude inward of the gate G2, and the protruding dimension of the throttle portion 106 is adjusted to set the dimensions of the upper and lower sides and the diagonal side of the opening of the second gate G2 in the inverted trapezoidal shape, thereby finally setting the opening area of the second gate G2.

The opening area of the third gate G3 is set based on the flow length of the resin injected from the third gate G3 flowing to both ends of the cavity 103 in the longitudinal direction, and is set here as an opening area proportional to the flow length. Therefore, the height dimension and the top-bottom dimension of the opening of the inverted trapezoid of the third gate G3 are set to satisfy the set opening area.

In the present embodiment, the opening area of the third gate G3 is set to an area substantially equal to the opening area of the first gate G1. Thus, the configuration of the third gate G3 is the same as the first gate G1 shown in (a), (b) of fig. 7A. When the opening area of the third gate G3 is set to a size close to the opening area of the second gate G2, the opening area may be adjusted by forming the throttle portion 106 in the gate as shown in (a) and (B) in fig. 7B.

Fig. 8 is a diagram illustrating a gate structure in three molding apparatuses for molding lenses 2A, 2B, and 2C having different shapes. The longitudinal dimension of the lens molded by each molding device, that is, the longitudinal dimension W of the cavity of the mold, is equal to or longer than 1000 mm. Further, the width dimension of the cavity in the longitudinal direction is the same in the respective lenses 2A, 2B, and 2C, but the width dimension of both ends is increased in the order of the lenses 2A, 2B, and 2C. The same applies to the cavities of the lenses 2A, 2B, and 2C, in which a first gate G1 is disposed at the center in the longitudinal direction, a second gate G2 is disposed at a position 290mm away from both sides of the first gate G1, and a third gate G3 is disposed at a position 290mm further away from both sides of the first gate G1.

Therefore, the flow length of the resin injected from the first gate G1 and flowing in the cavity is substantially the spacing dimension L1 between the first gate G1 and the second gate G2, and the flow length of the resin injected from the second gate G2 and flowing in the cavity is substantially the spacing dimension L2 between the second gate G2 and the third gate G3. The dimensions L1 and L2 are the same for the lenses 2A, 2B, and 2C.

On the other hand, the resin injected from the third gate G3 flows in the cavity to reach both ends, and then flows in the width direction along the inner surface of the cavity. Therefore, the flow length L3 of the resin differs depending on the width of the both ends in the longitudinal direction of the lens, and the flow length L3 is longer in the lens 2B than in the lens 2A and is longer in the lens 2C than in the lens 2B. Here, the opening area of the third gate G3 of each of the lenses 2A, 2B, and 2C is set to an area proportional to the flow length L3, and the opening area of the lens 2A, 2B, and 2C is set to an area proportional to the flow length L3The opening area of each third gate G3 was set to 15mm²、28.5mm²、33.3mm²。

In order to form a lens using the forming apparatus having the above structure, the above-described sequential forming is used. Fig. 9 is a schematic diagram for explaining the flow of the resin in the cavity 103. First, a resin is injected into the cavity 103 from the first gate G1 through a resin injection portion not shown. The injected resin R1 flows toward both sides in the longitudinal direction in the cavity 103, and the flow front end thereof reaches the second gate G2 at a timing after a predetermined time has elapsed.

At this timing, the resin is injected from the second gate G2. The resin R2 injected from the second gate G2 and the resin R2 injected from the first gate G1 are mixed and integrated, and further flow toward both sides in the longitudinal direction of the cavity 103. Since the opening area of the first gate G1 is larger than that of the second gate G2, the resin R1 flowing from the first gate G1 has a larger capacity than that from the second gate G2, and the heat capacity is also large, so that the temperature decrease during the period until reaching the second gate G2 is small. Further, by mixing with the high-temperature resin R2 injected from the second gate G2, the temperature of the resin R1 is suppressed from decreasing, and the generation of weld lines is suppressed.

When the flow front ends of the resins R1 and R2 in the mixed first gate G1 and second gate G2 reach the third gate G3, the resin is injected from the third gate G3. The resin R3 injected from the third gate G3 is mixed with the flowing resins R1 and R2 to be integrated, and flows toward both ends in the longitudinal direction of the cavity 103. Since the resins R1 and R2 from the first gate G1 and the second gate G2 have large capacities and large heat capacities, the temperature decrease during the period until reaching the third gate G3 is small, and the resins R3 injected from the third gate G3 and having high temperatures are mixed with each other, whereby further temperature decrease is suppressed and the occurrence of weld lines is suppressed.

Since the resin from the third gate G3 flows toward both ends of the cavity and flows from the longitudinal direction to the width direction along the inner surface of the cavity 103 at both ends, the flow length of the resin R3 is longer than the dimension from the third gate G3 to both ends of the cavity 103. Since the third gate G3 is set to an opening area substantially proportional to the flow length L3 of the resin in both ends of the cavity 103, an amount of the resin corresponding to the difference in the flow length L3 is injected from the third gate G3. Accordingly, in the molding of each of the lenses 2A, 2B, and 2C, the cavity 103 is filled at substantially the same time in each process, and therefore, in the molding of any of the lenses 2A, 2B, and 2C, the temperature of the injected resin can be suppressed from decreasing, and the occurrence of weld lines can be suppressed.

By setting the opening areas of the first gate G1 to the third gate G3 appropriately in this way, the temperature of the resin flowing in the cavity during the sequential molding can be managed with high accuracy, the occurrence of weld lines can be effectively suppressed, and the injection timing of each of the gates G1 to G3 during the sequential molding can be easily controlled. This enables molding of a high-quality molded article, i.e., a high-quality lens without a weld line.

In the lenses 2A, 2B, and 2C molded by the molding apparatus 100, as in the lens 2 shown in fig. 2 and 4, five gate pieces 25(G1 to G3) are present along the side edge of the lens 2, which are generated from the gates from the first gate G1 to the third gate G3. As described above, the gate piece 25 is cut and removed by the gate cutting step, and automatic cutting by a mechanical force by a robot and manual cutting by a manual operation are performed in the gate cutting step.

In the present embodiment, as in the schematic shape shown in fig. 7A (c), the cross-sectional area of the portions of the gate pieces 25(G1, G3) that are connected to the leg portions 23, which are generated by the first gate G1 and the third gate G3 having relatively large gate opening areas, is larger than the cross-sectional area of the gate piece 25(G2) generated by the second gate G2 shown in fig. 7B (c). In particular, the gate piece 25(G1, G3) has a larger thickness dimension than the gate piece 25 (G2). Therefore, manual cutting is difficult and removal is performed by automatic cutting. On the other hand, the cross-sectional area of the gate piece 25(G2) due to the second gate G2 is relatively small in thickness by the throttle portion 106, and therefore, the gate piece can be cut by manual work and removed by manual cutting.

In this way, in the five gate pieces 25(G1 to G3), two gate pieces 25(G2) are cut and removed by manual work, and the number of steps for automatic cutting by the robot is only three steps for the gate piece 25(G1) and the third gate piece 25(G3), and the number of steps can be reduced as compared with five steps required for automatic cutting of all five gate pieces 25(G1 to G3). This shortens the time of the gate cutting step, and as a result, the manufacturing cost of the lens can be reduced. Further, the lens can be cut and removed by manual cutting at an appropriate timing after molding, for example, when the lens is transported, and the influence on the process is small.

In the embodiment, an example in which five gates are arranged in the longitudinal direction of a lens as an injection molded article is shown, but the present invention can be applied to an injection molded article having a structure in which a first gate is arranged at the center in the longitudinal direction and second gates are arranged on both sides thereof, that is, an injection molded article having at least three gates. Therefore, a structure having more gates than the embodiment may be employed.

Although it depends on the shape and width of the injection-molded article, the present invention is preferably applied to an injection-molded article having a length of at least more than 1000mm, a molding method for molding the injection-molded article, and a molding apparatus. The first gate mark or the first gate may not be at the center in the longitudinal direction of the injection molded article or the molding apparatus, and may be at a position close to the center.

The present invention can be applied to a technique for molding a long and thin injection molded article by injection molding, and therefore the type of the molded article, the structure of the molding die, the molding material, and the like are not limited by the structure of the embodiment. In particular, the dimension of the gap between the first gate and the second gate, and the dimension of the gap between the second gate and the third gate can be appropriately set according to the shape of the injection molded article.

Claims

1. An injection-molded article which is a molded article formed into a shape that is long at least in one direction,

in this molded article, a plurality of gate marks are present along the longitudinal direction thereof, and the cross-sectional area of a first gate mark present at the center of the molded article in the longitudinal direction is larger than the cross-sectional area of a second gate mark present on both sides of the first gate mark.

2. The injection molding article of claim 1,

third gate marks are respectively arranged at the outer sides of the second gate marks in the length direction, and the cross section of each third gate mark is larger than that of each second gate mark.

3. The injection molding form of claim 1 or 2,

the cross-sectional shape of each gate mark is trapezoidal.

4. The injection molding article of claim 3,

the thickness dimension of the second gate mark is smaller than the thickness dimension of the first gate mark.

5. A molding apparatus having a cavity formed in a shape elongated in at least one direction, a plurality of gates arranged along a longitudinal direction of the cavity, and a resin injected into the cavity from each of the plurality of gates, characterized in that,

the gate includes:

a first gate which is arranged at a position close to the center of the cavity in the length direction and has a required opening area; and

and a second gate which is arranged on both sides of the first gate and has an opening area smaller than that of the first gate.

6. Forming device according to claim 5,

third gates are arranged on the outer sides of the second gates in the longitudinal direction, and the opening areas of the third gates are set to areas proportional to the flow lengths of the resin injected from the third gates.

7. Forming device according to claim 5 or 6,

the openings of the plurality of gates are formed in a trapezoidal shape, and at least the trapezoidal height dimension of the second gate is smaller than the trapezoidal height dimension of the first gate.