CN110561701A - cross core pulling structure and injection mold - Google Patents

Abstract

The invention provides a cross core-pulling structure and an injection mold, wherein the cross core-pulling structure comprises: the first core pulling body, the second core pulling body penetrating through the first core pulling body, the first I-shaped groove seat and the second I-shaped groove seat; the movable base plate is fixed with the first I-shaped groove seat and the second I-shaped groove seat, and the elastic pieces are clamped between the bottom of the movable mold and the movable base plate; when the mold is opened, the movable base plate drives the first I-shaped groove seat and the second I-shaped groove seat to move reversely at the same time under the elastic action of the elastic element, so that the first core-pulling body and the second core-pulling body which are correspondingly connected in a sliding manner move reversely along the length direction of the core-pulling bodies to realize core-pulling and back-off at the same time; the second core pulling body penetrates through the first core pulling body and drives the die assembly and the core pulling through the same movable base plate, so that the size of the die is reduced, and the structure of the die is more compact.

Description

Cross core pulling structure and injection mold

Technical Field

The invention belongs to the technical field of mold injection, and particularly relates to a cross core-pulling structure which is compact in structure and can realize simultaneous core pulling of two unconnected back-off structures of an injection product, and an injection mold comprising the cross core-pulling structure.

Background

with the rapid development of the automobile lamp industry, the appearance of the lamp is more and more dazzling and changeable, and correspondingly, the shapes of all parts are also varied, so that the requirements on the mold are higher and higher, more and more special part structures or shapes challenge the mold, and the mold is required to be realized. For example, in the existing partial vehicle lamp lens, two unconnected inverted structure regions are designed on the inner side of a product foot, so that after the injection molding of a mold is completed, the two inverted structure regions are subjected to cross core pulling, and the smooth demolding of the product can be ensured.

At present, the drive structure of loosing core in common among the injection mold is as shown in fig. 5, however, if cross loose core adopts this drive structure of loosing core in, then interior sliding block moving direction of loosing core must also can intersect, no matter be that little sliding block passes big sliding block, or big sliding block staggers in the space, and two kinds of schemes all can make the mould structure complicated finally.

Disclosure of Invention

The present invention has been made to solve the above problems, and an object of the present invention is to provide a cross core pulling structure that is compact and can simultaneously pull cores in two unconnected inverted buckling structures of an injection molded product, and an injection mold including the cross core pulling structure.

The invention provides a cross core-pulling structure which is arranged on a movable die of an injection mold and is used for simultaneously pulling and releasing a back-off button of an injection product with two unconnected back-off structure areas at one time, and the cross core-pulling structure is characterized by comprising the following components: a first core pulling assembly comprising: the first core pulling body is connected with the first core pulling body in a sliding mode; a second core pulling assembly comprising: the second core pulling body penetrates through the first core pulling body in a crossed angle mode, and a second I-shaped groove seat is connected with the second core pulling body in a sliding mode; the drive assembly looses the core contains: the movable base plate is fixedly connected with the first I-shaped groove seat and the second I-shaped groove seat, and the elastic pieces are clamped between the bottom of the movable mold and the movable base plate.

The cross core pulling structure provided by the invention can also be characterized in that the injection mold is arranged on an injection molding machine tool, when the mold is closed, the injection molding machine tool applies mold closing locking force, when the mold is opened, the fixed mold is separated from the movable mold, the mold closing locking force disappears, the movable base plate recovers the bouncing state under the elastic action of the elastic piece and leaves away from the movable mold, the first I-shaped groove seat and the second I-shaped groove seat are driven to simultaneously move towards the direction far away from the fixed mold, so that the first core pulling body and the second core pulling body which are correspondingly connected in a sliding manner simultaneously move along the length direction of the first core pulling body and the direction far away from the fixed mold and leave the injection molding position, and thus the simultaneous core pulling and.

In the cross core pulling structure provided by the invention, the cross core pulling structure can also have the characteristics that the bottom of the movable mold is provided with a plurality of movable mold side grooves; the top of the movable base plate is provided with a plurality of base plate side grooves, and the positions of the plurality of movable mould side grooves and the positions of the plurality of base plate side grooves are in one-to-one correspondence and are respectively used for installing the elastic pieces.

in the cross core pulling structure provided by the invention, each elastic element can be fixed in the movable mould side groove and the backing plate side groove through a limit screw, and in an initial state, the movable backing plate is abutted with the limit screw to enable each elastic element to be in a pre-tightening state; when the die is closed, the movable base plate moves along the axial direction of the limiting screw so as to compress the elastic piece.

The cross core pulling structure provided by the invention can also have the characteristic that the elastic element is a spring, and the first I-shaped groove seat and the second I-shaped groove seat are fixedly connected with the movable backing plate through screws respectively.

The cross core pulling structure provided by the invention can also have the characteristic that the first I-shaped groove seat and the second I-shaped groove seat are respectively provided with an I-shaped groove, and the first core pulling body and the second core pulling body are respectively provided with a sliding bulge in sliding fit with the I-shaped grooves.

the cross core pulling structure provided by the invention can also have the characteristic that the first core pulling body is axially provided with a through hole which penetrates in the radial direction, and the size of the through hole is matched with the radial size of the second core pulling body, so that the second core pulling body can axially and freely move in the through hole when the first core pulling body and the second core pulling body move simultaneously, and core pulling is carried out simultaneously with the first core pulling body.

the cross core pulling structure provided by the invention can also be characterized in that the movable mold and the movable base plate are connected through four guide posts for positioning and guiding, one end of each guide post is fixedly connected with the movable base plate, and the other end of each guide post can move back and forth in the guide sleeve arranged in the through hole of the movable mold.

In addition, the invention also provides an injection mold which is characterized by comprising the cross core-pulling structure with any structure.

Action and Effect of the invention

According to the cross core pulling structure and the injection mold, when the mold is closed, the movable mold moves towards the fixed mold, under the action of the mold closing locking force, the movable base plate moves towards the movable mold through the compression elastic piece until the movable base plate is attached to the bottom surface of the movable mold, the first I-shaped groove seat and the second I-shaped groove seat are driven to simultaneously move towards the fixed mold, and the first core pulling body and the second core pulling body which are correspondingly connected in a sliding mode simultaneously move along the length direction of the first core pulling body and the second core pulling body and towards the fixed mold so as to reach the injection; when the mold is opened, the mold closing locking force disappears, the movable base plate restores the springing-open state under the elastic action of the elastic piece and leaves the movable mold, and the first I-shaped groove seat and the second I-shaped groove seat are driven to simultaneously move towards the direction far away from the fixed mold, so that the first core pulling body and the second core pulling body which are correspondingly connected in a sliding manner simultaneously move along the length direction of the core pulling bodies and the direction far away from the fixed mold and leave the injection molding position, and one-time simultaneous core pulling and back off-off is realized; and the second core pulling body is designed to penetrate through the first core pulling body and drive the die assembly and the core pulling through the same movable base plate, so that the size of the die is reduced, and the structure of the die is more compact.

drawings

Fig. 1 is a schematic structural diagram of a lens for a vehicle lamp according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a mold opening state of the cross core-pulling structure in the embodiment of the invention.

fig. 3 is a schematic view of an i-shaped groove seat connection structure in an embodiment of the invention.

Fig. 4 is a schematic structural diagram of a mold clamping state of the cross core-pulling structure in the embodiment of the invention.

FIG. 5 is a schematic view of an internal core pulling transmission structure in the prior art.

Detailed Description

The invention is further illustrated by the following examples, which are not intended to limit the scope of the invention.

< example >

Fig. 1 is a schematic structural diagram of a lens for a vehicle lamp according to an embodiment of the present invention.

Fig. 1 shows a vehicle lamp lens 101, and two unconnected inverted regions, namely a large-range inverted region 102 and a small-range inverted region 103, are present on the vehicle lamp lens 101. Therefore, when the injection molding is carried out on the vehicle lamp lens, after the injection molding is completed, the core pulling needs to be carried out on the two inverted buckle areas in a crossed manner, so that the smooth demolding of the product can be ensured.

Fig. 2 is a schematic structural diagram of a mold opening state of the cross core-pulling structure in the embodiment of the invention.

As shown in fig. 2, the present embodiment provides a cross core pulling structure 100 applied in an injection mold, which can realize the cross core pulling of a vehicle lamp lens 101 shown in fig. 1 after the injection molding is completed. The cross core pulling structure 100 is arranged on a movable mold 200 of an injection mold and is used for simultaneously pulling and releasing a back-off core at one time for an injection product with two unconnected back-off structure areas as shown in fig. 1. The cross core-pulling structure 100 includes: a first core back assembly 10, a second core back assembly 20 and a core back driving assembly 30.

the first core pulling assembly 10 comprises: a first core body 11 and a first I-shaped groove seat 12.

fig. 3 is a schematic view of an i-shaped groove seat connection structure in an embodiment of the invention.

As shown in fig. 2, the first core body 11 has a substantially rectangular columnar shape, and the top thereof has an end surface matching the wide range inverted region 102 of the lens 101; a through hole 13 is provided in an axial region of the first core body 11, and the through hole 13 is provided so as to penetrate in a radial direction of the first core body 11.

In addition, as shown in fig. 3, the bottom of the first drawer body 11 has a slide projection 14.

The first i-shaped groove seat 12 is connected with the first drawer core 11 in a sliding fit manner, as shown in fig. 3, the first i-shaped groove seat 12 is provided with an i-shaped groove 15, and the size of the i-shaped groove 15 is matched with the size of the sliding protrusion 14 of the first drawer core 11, so that the sliding protrusion 14 can be clamped in the i-shaped groove 15 and can slide back and forth along the i-shaped groove 15.

The second core pulling assembly 20 includes: a second core body 21 and a second i-shaped groove seat 22.

As shown in fig. 2, the second core body 21 has a substantially rectangular columnar shape, and the top thereof has an end surface matching the small-range inverted region 103 of the lens 101; thus, the overall size of the second wick body 21 is smaller than that of the first wick body 11. The top of the second core body 21 extends out of the through hole 13 of the first core body 11, so that a certain crossing angle is formed between the second core body 21 and the first core body 11, and the crossing angle is mainly influenced by the positions of two inverted structure areas of the injection molding product.

In addition, the size of the through hole 13 matches with the radial size of the second core body 21, specifically: the size of the through hole 13 needs to be larger than the radial size of the second core body 21, so that when the first core body 11 and the second core body 21 move simultaneously during mold opening and closing, the second core body 21 can move back and forth in the through hole 13 without any interference, and thus, the first core body 11 and the second core body 21 can be ensured to move simultaneously without mutual interference. Therefore, the size of the through-hole 13 needs to be able to accommodate the second core body 21 during mold opening and mold closing, respectively, because the position of the through-hole 13 relative to the second core body 21 during mold opening and mold closing is different, that is, the size of the through-hole 13 needs to take into account the influence of the mold opening and closing movement. In the present embodiment, in both the mold opening and mold closing states, the minimum clearance between the second core body 21 and the wall of the through hole 13 is ensured to be 2-3 mm.

The second i-shaped groove seat 22 is connected with the second drawer core 21 in a sliding fit, in this embodiment, the sliding connection manner of the second i-shaped groove seat 22 and the second drawer core 21 is the same as the sliding connection manner of the first i-shaped groove seat 12 and the first drawer core 11, that is, the second drawer core 21 also has a sliding protrusion like the sliding protrusion 14 shown in fig. 3, and the second i-shaped groove seat 22 also has an i-shaped groove like the i-shaped groove 15 shown in fig. 3, so that the sliding protrusion of the second drawer core 21 can slide back and forth along the second i-shaped groove seat 22.

As shown in fig. 2, the core back driving assembly 30 includes: a movable pad 31 and eight elastic members 32.

the movable base plate 31 is positioned and guided by the through connection of four guide posts, not shown, with the movable mold 200, and in an initial state, the movable base plate 31 is spaced from the bottom 201 of the movable mold 200 by a certain distance H. One end of each guide post is fixedly connected with the movable backing plate 31, and the other end of each guide post can move back and forth in the guide sleeve installed in the through hole penetrating through the movable die 200, namely, the movable backing plate 31 and the guide post integrally move relative to the movable die 200. Here, the guide post is used in cooperation with the guide bush to guide the movement of the movable pad 31.

The first i-shaped groove seat 12 and the second i-shaped groove seat 22 are fixedly connected with the movable backing plate 31 through screws, so that when the movable backing plate 31 moves, the first i-shaped groove seat 12 and the second i-shaped groove seat 22 can be driven to move synchronously, the sliding protrusions of the first drawer body 11 and the second drawer body 21 are further driven to slide back and forth along the corresponding i-shaped grooves, and therefore the first drawer body 11 and the second drawer body 21 move along respective length directions, namely, the injection molding position and the initial position are switched, and the process of restoring the first drawer body 11 and the second drawer body 21 from the injection molding position to the initial position is the core pulling process.

The eight elastic members 32 are clamped between the bottom 201 of the movable mold 200 and the movable backing plate 31, specifically: the movable die plate 31 has eight die side grooves 33 at the top, the movable die 200 has eight movable die side grooves 202 at the bottom, and the eight die side grooves 33 correspond to the eight movable die side grooves 202 in position one by one, and are used for mounting eight elastic members 32 respectively.

Each elastic member 32 is fixed in the corresponding movable mold side groove 202 after penetrating through the corresponding pad side groove 33 by a limit screw, and at this time, the elastic member 32 is sleeved on the limit screw. In the initial state, the movable backing plate 31 abuts against the limit screw, so that each elastic member 32 is in a pre-tightening state. Here, the axial direction of the limit screw is identical to the axial direction of the guide posts, and when the mold clamping is performed, the four guide posts move in the corresponding guide sleeves, so that the movable shim plate 31 moves axially along the limit screw to further compress the elastic member 32 until the movable shim plate 31 is attached to the bottom portion 201 of the movable mold 200. In the present embodiment, the elastic member 32 is a spring.

Based on the cross core-pulling structure 100, the specific process of applying the cross core-pulling structure to an injection mold to inject the lens 101 of the vehicle lamp is as follows:

Firstly, installing a mold, installing an injection mold containing the cross core-pulling structure 100 on an injection molding machine tool, wherein a fixed mold of the injection mold is positioned on one side, a movable mold of the injection mold is positioned on the other side, and the cross core-pulling structure 100 is arranged on the movable mold.

fig. 4 is a schematic structural diagram of a mold clamping state of the cross core-pulling structure in the embodiment of the invention.

The mold closing and injection molding process comprises the following steps: the movable die 200 moves towards the fixed die, under the action of a die locking force applied by an injection molding machine tool, the movable base plate 31 moves towards the movable die through the compression elastic piece 32 until the movable base plate 31 is attached to the bottom 201 of the movable die 200, the first i-shaped groove seat 12 and the second i-shaped groove seat 22 are driven to simultaneously move towards the fixed die, the sliding protrusions of the first drawer core body 11 and the second drawer core body 21 are further driven to simultaneously slide along the corresponding first i-shaped groove seat 12 and the second i-shaped groove seat 22, and the first drawer core body 11 and the second drawer core body 21 move towards the fixed die along the length direction of the first drawer core body and the length direction of the second drawer core body to reach an injection molding position, so that the state shown in fig. 4. At this time, the first core body 11 and the second core body 21 jointly form a cavity of the lens 101, that is, the first core body 11 and the second core body 21 participate in the injection molding process. After the mold closing is completed, an injection molding process is performed, which is the prior art and is not described herein again.

The die opening and core pulling process comprises the following steps:

The movable mold 200 is separated from the fixed mold, the mold closing locking force disappears, at this time, the movable base plate 31 recovers the springing-open state under the elastic action of the elastic member 32 and is far away from the movable mold, the first i-shaped groove seat 12 and the second i-shaped groove seat 22 are driven to move towards the direction far away from the fixed mold, the sliding protrusions of the first core pulling body 11 and the second core pulling body 21 are further driven to slide reversely along the corresponding first i-shaped groove seat 12 and the second i-shaped groove seat 22, the first core pulling body 11 and the second core pulling body 21 are driven to move along the length direction of the first core pulling body and the direction far away from the fixed mold and are far away from the injection molding position, and therefore the core pulling and the back buckling are achieved simultaneously, and the state shown in.

This embodiment also provides an injection mold based on above-mentioned cross loose core structure, and this injection mold includes the cross loose core structure of above-mentioned this embodiment.

Effects and effects of the embodiments

According to the cross core pulling structure and the injection mold related to the embodiment, during mold closing, the movable mold moves towards the fixed mold, under the action of mold closing locking force, the movable base plate moves towards the movable mold through the compression elastic piece until the movable base plate is attached to the bottom surface of the movable mold, the first I-shaped groove seat and the second I-shaped groove seat are driven to simultaneously move towards the fixed mold, so that the sliding protrusions of the first core pulling body and the second core pulling body simultaneously slide along the corresponding first I-shaped groove seat and the second I-shaped groove seat, and the first core pulling body and the second core pulling body are driven to simultaneously move along the length direction of the first core pulling body and the direction of the fixed mold so as to reach an injection molding; when the mold is opened, the mold closing locking force is relieved, the movable base plate restores the springing-open state under the elastic action of the elastic piece and leaves the movable mold, and the first I-shaped groove seat and the second I-shaped groove seat are driven to move towards the direction away from the fixed mold at the same time, so that the sliding protrusions of the first core pulling body and the second core pulling body simultaneously reversely slide along the corresponding first I-shaped groove seat and the second I-shaped groove seat, and the first core pulling body and the second core pulling body are driven to simultaneously reversely move along the length direction of the first core pulling body and the second core pulling body and move towards the direction away from the fixed mold to leave the injection molding position, and thus, the simultaneous core pulling and back; and the second core pulling body is designed to penetrate through the first core pulling body and drive the die assembly and the core pulling through the same movable base plate, so that the size of the die is reduced, and the structure of the die is more compact.

In this embodiment, the number of the elastic members is eight, but in the present invention, the number of the elastic members may also be six or other values, which can achieve the effect of the present invention.

While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and scope of the invention, and these changes and modifications are within the scope of the invention.

Claims (9)

1. The utility model provides a structure of loosing core alternately sets up on injection mold's movable mould for once loosing core and take off the back-off simultaneously to the injection moulding product that has two disconnected back-off structure regions, its characterized in that includes:

A first core pulling assembly comprising: the core pulling device comprises a first core pulling body and a first I-shaped groove seat in sliding connection with the first core pulling body;

A second core pulling assembly comprising: the second core pulling body penetrates through the first core pulling body in a crossed angle mode, and a second I-shaped groove seat is connected with the second core pulling body in a sliding mode;

The drive assembly looses the core contains: a movable base plate fixedly connected with the first I-shaped groove seat and the second I-shaped groove seat, and a plurality of elastic pieces clamped between the bottom of the movable die and the movable base plate,

When the injection mold is closed, the movable mold moves towards the fixed mold of the injection mold, under the action of the closing locking force, the movable base plate moves towards the elastic piece through compression, the movable mold moves until being attached to the bottom surface of the movable mold, the movable base plate drives the first I-shaped groove seat and the second I-shaped groove seat to move towards the fixed mold, and therefore the first core pulling body and the second core pulling body which are connected in a sliding mode can move towards the fixed mold along the length direction of the first core pulling body and the length direction of the second core pulling body simultaneously to reach the injection molding position.

2. The cross core pulling structure according to claim 1, wherein:

Wherein the injection mold is arranged on an injection molding machine,

When the mold is closed, the injection molding machine tool applies the mold closing locking force,

during the die sinking, the cover half with the movable mould separation, compound die locking force disappears, the activity backing plate is in resume the spring-open state under the elastic action of elastic component and leave the movable mould drives first I-shaped groove seat with the second I-shaped groove seat is kept away from simultaneously towards the direction of cover half removes for correspond sliding connection first core body with the second core body is loosed core simultaneously along its self length direction and towards keep away from the direction of cover half removes and leaves the position of moulding plastics, thereby realizes loosing core simultaneously and takes off the back-off.

3. the cross core pulling structure according to claim 2, wherein:

Wherein, the bottom of the movable mould is provided with a plurality of movable mould side grooves;

the top of the movable base plate is provided with a plurality of base plate side grooves,

The positions of the plurality of movable mould side grooves and the positions of the plurality of backing plate side grooves are in one-to-one correspondence and are respectively used for installing the elastic pieces.

4. The cross core pulling structure according to claim 3, wherein:

Wherein each of the elastic members is fixed in the movable die side groove and the pad side groove by a limit screw,

in an initial state, the movable base plate is abutted with the limit screw, so that each elastic part is in a pre-tightening state; when the die is closed, the movable base plate moves along the axial direction of the limiting screw so as to compress the elastic piece.

5. The cross core pulling structure according to claim 4, wherein:

Wherein the elastic piece is a spring,

The first I-shaped groove seat and the second I-shaped groove seat are fixedly connected with the movable cushion plate through screws respectively.

6. The cross core pulling structure according to claim 5, wherein:

Wherein the first I-shaped groove seat and the second I-shaped groove seat are respectively provided with an I-shaped groove,

the first core pulling body and the second core pulling body are respectively provided with a sliding bulge in sliding fit with the I-shaped groove.

7. The cross core pulling structure according to claim 6, wherein:

the first core pulling body is axially provided with a through hole which penetrates in the radial direction, and the size of the through hole is matched with the radial size of the second core pulling body, so that the second core pulling body can axially and freely move in the through hole when the first core pulling body and the second core pulling body move simultaneously, and core pulling is carried out on the first core pulling body and the second core pulling body simultaneously.

8. the cross core pulling structure according to claim 7, wherein:

Wherein the movable mold is connected with the movable base plate through four guide posts for positioning and guiding,

One end of each guide pillar is fixedly connected with the movable base plate, and the other end of each guide pillar can move back and forth in the guide sleeve arranged in the through hole of the movable die.

9. an injection mold comprising the cross core-pulling structure of any one of claims 1 to 8.