CN209955218U - Inclined core-pulling module - Google Patents

Abstract

The utility model relates to the technical field of mold, specifically be an oblique module of loosing core, including last mould, be located die cavity, lower mould, first slider on the terminal surface under the last mould and be used for holding the holding tank of first slider, the holding tank is located just communicate in the die cavity on the lower terminal surface of last mould, but first slider can follow the oblique downward direction and to keep away from die cavity direction sliding connection in holding tank, but the lower terminal surface horizontal slip of first slider matches in the up end of lower mould, is close to the side of die cavity and the lateral wall phase-match of die cavity on the first slider. The utility model has reasonable structure, when the die is closed, the first slide block slides along the oblique upward direction to the direction close to the die cavity to be matched with the die cavity under the extrusion of the lower die; during the die sinking, because the power of lower mould effect on first slider disappears, first slider slides along the oblique downward direction to keeping away from the die cavity direction under self action of gravity to avoid causing the scotch to the surface of shaping product, can improve the qualification rate of product, and then improve its market competition.

Description

Inclined core-pulling module

Technical Field

The utility model relates to the technical field of molds, specifically a module of loosing core to one side.

Background

With the rapid development of the automobile industry and the continuous improvement and promotion of living conditions of people, automobiles become one of indispensable transportation tools for people to take shape. The automobile keeping quantity is increased year by year, more and more people own private automobiles, and the popularization of automobiles brings development to the manufacture and design of automobile parts. Because the structure of the automobile is complex, the range of related parts is very wide and complex, and therefore, the reasonable structure and the strength of each part are required to meet the requirements, and the use requirements of the automobile can be met only in this way. In order to make the interior of the entire vehicle beautiful, the interior of the vehicle is covered with an interior cover, and the beauty and the installation reliability of the interior are the focus of attention of customers.

As shown in fig. 1, the automobile B-pillar trim (shown by reference numeral 100) is provided with a flanging structure (shown by reference numeral 101) and a plurality of arc-shaped flanging structures (shown by reference numeral 102), and when the automobile B-pillar trim is demolded, if a formed product is directly ejected through an ejector rod, scratches are easily formed on the outer surface of the automobile B-pillar, so that the appearance of the product is influenced, the rejection rate of the product is increased, and the market competitiveness of the product is greatly reduced; over time, the mold itself is also susceptible to damage, reducing its useful life. To this end, we propose a mold for producing an automotive B-pillar trim panel.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a mould for producing car B post plaque, its is rational in infrastructure, and the drawing of patterns is simple and be difficult for causing the damage to the product.

Another object of the utility model is to provide a module of loosing core to one side, its is rational in infrastructure, is difficult for causing the damage to the product after the shaping when the drawing of patterns.

In order to achieve the above object, the utility model provides a following technical scheme: a mold for producing an automobile B-column decorative plate comprises an upper mold, a cavity, a lower mold, a mold core, a guide mechanism, a demolding mechanism and a core-pulling mechanism, wherein the cavity is positioned on the lower end face of the upper mold, the mold core is positioned on the upper end face of the lower mold and arranged in a manner of facing the cavity, and a hot runner communicated with the mold core is arranged on the lower end face of the lower mold; the guide mechanism comprises a plurality of circular guide pillars, the lower ends of the circular guide pillars are vertically arranged on the upper end surface of the lower die, and circular guide grooves are formed in the positions, corresponding to the circular guide pillars, on the lower end surface of the upper die; the demolding mechanism comprises a bottom plate and a plurality of ejector rods, the bottom plate can be movably connected to the lower part of the lower mold up and down, the lower ends of the ejector rods are vertically arranged on the bottom plate, and the upper ends of the ejector rods penetrate through the lower mold and are flush with the upper end surface of the mold core; the core pulling mechanism comprises a plurality of inclined core pulling modules and a plurality of side core pulling modules, and the inclined core pulling modules are arranged on the side edge of the cavity and can be connected to the lower end of the upper die in a sliding manner along the inclined downward direction in the direction away from the cavity; the side core-pulling modules are uniformly distributed on the left side and the right side of the mold core and can be connected to the upper end of the lower mold in a sliding manner along the horizontal direction and the direction far away from the mold core.

The beneficial effects of the utility model reside in that: the utility model has reasonable structure and strong practicability; the inclined core pulling module can slide in a direction away from the cavity in an inclined downward direction, and the side core pulling module can slide in a direction away from the core in a horizontal direction, so that the inclined core pulling module can slide in a direction away from the cavity in an inclined downward direction during mold opening, the lower mold can conveniently carry the formed automobile B column decorative plate to move downwards, and the side surface of the cavity can be prevented from scratching the outer surface of the formed automobile B column decorative plate when the formed automobile B column decorative plate is separated from the upper mold; after the lower die and the upper die are separated, the side core pulling module slides in the direction away from the mold core along the horizontal direction, so that the lower die is prevented from scratching the outer surface of the formed automobile B column decorative plate when the formed automobile B column decorative plate is separated from the lower die; through the utility model discloses car B post plaque of production, its outer surface does not have the scotch, and the qualification rate of product is high to be favorable to improving its market competition.

Preferably, the inclined core pulling module comprises a first slider and a holding tank used for holding the first slider, the holding tank is located on the lower end face of the upper die and communicated with the die cavity, the first slider can be connected to the holding tank in a sliding mode along the direction of the inclined downward direction away from the die cavity, the lower end face of the first slider can be matched with the upper end face of the lower die in a horizontal sliding mode, and the first slider is close to the side face of the die cavity and matched with the side wall of the die cavity. The advantages are that: when the die is closed, under the extrusion of the lower die, the first sliding block slides towards the direction close to the die cavity along the obliquely upward direction, so that the first sliding block is matched with the die cavity; when the mold is opened, the force of the lower mold on the first sliding block disappears, and the first sliding block slides in the direction away from the cavity in the obliquely downward direction under the action of gravity, so that the outer surface of a molded product is prevented from being scratched.

Preferably, the first sliding block can be slidably connected to the accommodating groove along an obliquely downward direction in a direction away from the cavity, that is, a guide rail arranged along the obliquely downward direction in the direction away from the cavity is arranged in the accommodating groove, and the first sliding block is provided with a guide groove used for being slidably connected with the guide rail. The advantages are that: because the lower end surface of the first sliding block can be matched with the upper end surface of the lower die in a horizontal sliding manner, when the lower die is closed, the first sliding block can slide towards the direction close to the cavity along the guide rail under the extrusion of the lower die; when the mold is opened, at the moment that the lower mold is separated from the upper mold, the first sliding block can slide in the direction away from the cavity along the guide rail due to the gravity action of the first sliding block.

Preferably, a first oil storage groove is formed in the surface of the guide rail, which is in contact with the guide groove. The advantages are that: the sliding fluency and the heat dissipation performance of the first sliding block along the guide rail can be improved.

Preferably, an elastic member for making the first slider slide in a direction away from the cavity in a diagonally downward direction and a limiting member for preventing the first slider from disengaging from the accommodating groove are arranged between the first slider and the accommodating groove. The advantages are that: when the die is opened, the elastic piece can automatically enable the first sliding block to slide along the guide rail in the direction away from the cavity, so that the first sliding block is prevented from being bonded in the accommodating groove; the locating part can avoid the first slider with the holding tank separation.

Preferably, the elastic member includes a plurality of springs arranged along the sliding direction of the first slider, one end of each spring is mounted at the inner bottom of the accommodating groove, and the other end of each spring is mounted on the upper end surface of the first slider. The advantages are that: the first sliding block is prevented from being bonded in the accommodating groove when the mold is opened.

Preferably, the limiting part comprises a plurality of limiting blocks installed at the outlet of the accommodating groove, and a limiting sliding groove used for being matched with the limiting blocks is formed in the first sliding block along the sliding direction of the first sliding block. The advantages are that: the first slider can be prevented from being separated from the accommodating groove.

Preferably, a positioning piece is further arranged between the first sliding block and the accommodating groove, the positioning piece comprises a plurality of positioning pins arranged along the sliding direction of the first sliding block, a plurality of positioning blocks arranged along the sliding direction of the first sliding block and a plurality of positioning grooves used for being matched with the positioning blocks, one end of each positioning pin is installed at the inner bottom of the accommodating groove, and the lower end of the first sliding block is provided with a positioning pin hole used for being movably matched with the other end of each positioning pin; the positioning blocks are integrally installed on the side wall of the first sliding block, and the positioning grooves are located on the side wall of the accommodating groove. The advantages are that: the matching between the positioning pin and the positioning pin hole can enhance the matching precision between the first sliding block and the cavity; the matching between the positioning block and the positioning groove can reduce the swing amplitude of the first sliding block, and further enhance the matching precision between the first sliding block and the cavity.

Preferably, an L-shaped hook is vertically arranged on the lower end face of the first sliding block, the hook-shaped end of the L-shaped hook faces one side of the cavity, and an inverted L-shaped hook used for hooking with the L-shaped hook is arranged at the upper end of the lower die. The advantages are that: when the adhesive force between the first sliding block and the accommodating groove is too large, the inverted L-shaped hook on the lower die can hook the L-shaped hook, so that the first sliding block is pulled to slide along the guide rail in the direction away from the cavity, and at the moment, the L-shaped hook can horizontally move until being separated from the inverted L-shaped hook.

Preferably, the L-shaped hook and the inverted L-shaped hook are respectively provided with an arc-shaped notch which is convenient for realizing hooking and separation between the L-shaped hook and the inverted L-shaped hook. The advantages are that: the L-shaped hook and the inverted L-shaped hook are hooked and separated conveniently.

Preferably, a first insert is embedded on the surface of the first sliding block, which is in contact with the accommodating groove, and a second oil storage groove is formed in the outer surface of the first insert. The advantages are that: and the sliding fluency and the heat dissipation performance of the first sliding block are improved.

Preferably, the side core-pulling module comprises a second sliding block, a second air cylinder and a sliding groove which is located on the upper end surface of the lower die and used for accommodating the second sliding block to slide along the horizontal direction and far away from the mold core, the second sliding block is connected to the sliding groove in a sliding mode through the second air cylinder, and the side face, close to the mold core, of the second sliding block is matched with the side wall of the mold core. The automobile B-pillar decorative plate forming machine has the advantages that the second sliding block can be controlled to slide in the direction away from the mold core along the horizontal direction through the second cylinder, so that the lower mold can be prevented from scratching the outer surface of the formed automobile B-pillar decorative plate when the formed automobile B-pillar decorative plate is separated from the lower mold.

Preferably, the upper end of the second sliding block is integrally and upwards provided with a limiting boss, and a limiting groove used for being matched with the limiting boss is formed in the position, corresponding to the limiting boss, of the upper die. The advantages are that: after the die is closed, the matching precision between the second sliding block and the mold core can be improved due to the matching between the limiting boss and the limiting groove.

Preferably, the outer surfaces of the second sliding block and the limiting boss are embedded with a second insert, and a third oil storage tank is arranged on the outer surface of the second insert. The advantages are that: the smoothness and the heat dissipation performance of the matching between the second sliding block and the sliding groove and between the limiting boss and the limiting groove are improved.

Preferably, last mould and lower mould between still be equipped with positioning mechanism, positioning mechanism include an organic whole connect in first location lug and an organic whole connect in on the four corners position on the up end of lower mould second location lug on the intermediate position, just go up the mould be equipped with on the lower terminal surface be used for with first location lug assorted first constant head tank and be used for with second location lug assorted second constant head tank. The advantages are that: through cooperation between first locating lug and the first constant head tank and the cooperation between second locating lug and the second constant head tank, improved last mould and lower mould between the precision of cooperation.

Preferably, a third insert is embedded on the outer surface of the second positioning lug, and a fourth oil storage groove is formed in the outer surface of the third insert. The advantages are that: the smoothness and the heat dissipation performance of the matching between the second positioning lug and the second positioning groove are improved.

Preferably, the guide mechanism further comprises a plurality of square guide pillars, the plurality of square guide pillars are vertically installed at the upper end of the lower die, and square guide grooves are formed in positions, corresponding to the plurality of square guide pillars, on the upper die. The advantages are that: the positioning precision between the upper die and the lower die is improved.

Drawings

Fig. 1 is a schematic perspective view of a molded product according to a preferred embodiment of the present invention;

fig. 2 is a schematic perspective view of a mold according to a preferred embodiment of the present invention;

fig. 3 is a schematic perspective view of a lower mold according to a preferred embodiment of the present invention;

fig. 4 is a schematic perspective view of an upper mold according to a preferred embodiment of the present invention;

fig. 5 is a schematic perspective view of an upper mold according to a preferred embodiment of the present invention (in a state where the inclined core pulling module is separated from the upper mold);

fig. 6 is a schematic perspective view of an inclined core pulling module according to a preferred embodiment of the present invention;

fig. 7 is an exploded perspective view of an inclined core pulling module according to a preferred embodiment of the present invention;

fig. 8 is a schematic view of the working principle of the L-shaped hook and the inverted L-shaped hook according to a preferred embodiment of the present invention.

Detailed Description

The following description will further describe embodiments of the present invention with reference to the accompanying drawings. The following examples are only used to illustrate the technical solutions of the present embodiments more clearly, and the protection scope of the present invention is not limited thereby.

Referring to fig. 1 to 8, in an embodiment of the present invention, a mold for producing a B-pillar trim of an automobile includes an upper mold 1, a cavity 11, a lower mold 2, a core 21, a guiding mechanism, a demolding mechanism 4, and a core-pulling mechanism, where the cavity 11 is located on a lower end surface of the upper mold 1 (in this embodiment, upper, lower, left, right, front, and rear directions respectively refer to upper, lower, left, right, front, and rear directions of a drawing in fig. 2), the core 21 is located on an upper end surface of the lower mold 2 and is arranged facing the cavity 11 (in this embodiment, there are two cavities 11 and two cores 21, respectively, so as to produce a set of B-pillar trim of an automobile, that is, a left pillar trim of an automobile and a right pillar trim of an automobile), and a hot runner 22 communicated with the core 21 is disposed on a lower end surface of the lower mold 2; the guide mechanism comprises a plurality of circular guide posts 31, the number of the circular guide posts 31 is preferably four, the lower ends of the four circular guide posts 31 are vertically arranged on the upper end surface of the lower die 2, and circular guide grooves 32 are arranged on the lower end surface of the upper die 1 corresponding to the four circular guide posts 31; the demolding mechanism 4 comprises a bottom plate 41 and a plurality of ejector rods 42, the bottom plate 41 can be movably connected to the lower part of the lower mold 2 up and down through a first air cylinder 43, the lower ends of the ejector rods 42 are vertically installed on the bottom plate 41, and the upper ends of the ejector rods 42 penetrate through the lower mold 2 and are flush with the upper end surface of the mold core 21, so that when the bottom plate 41 is driven to move upwards through the first air cylinder 43, the upper ends of the ejector rods 42 upwards eject a product embedded on the mold core 21; each core pulling mechanism comprises four inclined core pulling modules 5 and four side core pulling modules 6 (the number of the inclined core pulling modules 5 and the number of the side core pulling modules 6 are not limited to this, but at least one side edge of each cavity 11 is provided), and the four inclined core pulling modules 5 are respectively arranged on the side edges of the two cavities 11 and can be connected to the lower end of the upper die 1 in a sliding manner along an inclined downward direction in a direction away from the cavities 11; the four side core pulling modules 6 are uniformly distributed on the left side and the right side of the mold core 21 and can be connected to the upper end of the lower mold 2 in a sliding manner along the horizontal direction and the direction far away from the mold core 21.

In an embodiment, the inclined core pulling module 5 includes a first slider 51 and an accommodating groove 13 for accommodating the first slider 51, the accommodating groove 13 is located on the lower end surface of the upper die 1 and is communicated with the cavity 11, the first slider 51 can be connected to the accommodating groove 13 in a sliding manner along an inclined downward direction in a direction away from the cavity 11, the lower end surface of the first slider 51 can be matched with the upper end surface of the lower die 2 in a horizontal sliding manner, and a side surface of the first slider 51 close to the cavity 11 is matched with a side wall of the cavity 11. During mold closing, under the extrusion of the lower mold 2, the first slide block 51 slides in the direction approaching the cavity 11 along the obliquely upward direction, so that the side surface of the first slide block 51 is matched with the side wall of the cavity 11; when the mold is opened, because the force of the lower mold 2 acting on the first slide block 51 disappears, the first slide block 51 slides in the direction away from the cavity 11 along the inclined downward direction under the action of gravity, and the cavity 11 is prevented from scratching the outer surface of a molded product.

In an embodiment, the first slider 51 is slidably connected to the receiving groove 13 along a diagonally downward direction in a direction away from the cavity 11, that is, a guide rail 14 is disposed in the receiving groove 13 along the diagonally downward direction in a direction away from the cavity 11 (the rail 14 is mounted in the guide rail mounting groove 140 by a bolt), and the first slider 51 is provided with a guide groove 511 for slidably connecting with the guide rail 14. Because the lower end surface of the first slide block 51 can be matched with the upper end surface of the lower die 2 in a horizontal sliding manner, when the lower die 2 is closed, the first slide block 51 can slide along the guide rail 14 in the direction close to the cavity 11 under the extrusion of the lower die 2; when the mold is opened, at the moment the lower mold 2 is separated from the upper mold 1, the first slider 51 can slide in the direction away from the cavity 11 along the guide rail 14 due to the gravity of the first slider 51.

In an embodiment, a first oil reservoir 141 is disposed on a surface of the guide rail 14 contacting the guide groove 511, and the first oil reservoir 141 is preferably corrugated, and can store solid lubricant therein, which is beneficial to improve smoothness and heat dissipation of the first slider 51 sliding along the guide rail 14.

In an embodiment, an elastic member 52 for making the first slider 51 slide in a direction away from the cavity 11 along a downward direction and a limiting member 53 for preventing the first slider 51 from separating from the receiving slot 13 are disposed between the first slider 51 and the receiving slot 13. The advantages are that: the elastic piece 52 can automatically enable the first sliding block 51 to slide along the guide rail 14 in a direction away from the cavity 11 when the mold is opened, so that the first sliding block 51 is prevented from being bonded in the accommodating groove 13; the limiting member 53 can prevent the first slider 51 from being separated from the accommodating groove 13.

In an embodiment, the elastic member 52 includes a plurality of springs 521 arranged along the sliding direction of the first slider 51, the number of the springs 521 is preferably two, one end of the spring 521 is mounted at the inner bottom of the receiving groove 13, and the other end of the spring 521 is mounted at the upper end surface of the first slider 51. When the mold is closed, the first slider 51 is pressed into the accommodating groove 13 by the pressing of the lower mold 2, and the spring 521 is compressed; when the mold is opened, the acting force of the lower mold 2 disappears, and the first slider 51 is ejected by the elastic restoring force of the spring 521, so that the first slider 51 is prevented from being stuck in the accommodating groove 13.

In an embodiment, the limiting member 53 includes a plurality of limiting blocks 531 (as indicated by 5310 in fig. 5) installed at an outlet of the accommodating groove 13, the number of the limiting blocks 531 is preferably two, a limiting sliding groove 532 used for matching with the limiting blocks 531 is arranged on the first slider 51 along a sliding direction of the first slider, and under the limiting of the limiting sliding groove 532, the first slider 51 is prevented from being separated from the accommodating groove 13.

In an embodiment, a positioning element is further disposed between the first slider 51 and the accommodating groove 13, the positioning element includes a plurality of positioning pins 541 (the number of the positioning pins 541 is preferably two) disposed along the sliding direction of the first slider 51, a plurality of positioning blocks 542 (the number of the positioning blocks 542 is preferably one, and the shape of the positioning blocks 542 is preferably a boss shape, so as to facilitate entering the positioning groove 543), and a plurality of positioning grooves 543 for matching with the positioning blocks 542, one end of the positioning pins 541 is mounted at the inner bottom of the accommodating groove 13, and a positioning pin hole for movably matching with the other end of the positioning pins 541 is disposed at the lower end of the first slider 51; the positioning block 542 is integrally mounted on the sidewall of the first slider 51, and the positioning groove 543 is located on the sidewall of the accommodating groove 13. The matching between the positioning pin 541 and the positioning pin hole can enhance the matching precision between the side surface of the first slide block 51 and the side wall of the cavity 11; the fitting between the positioning block 542 and the positioning groove 543 can reduce the swing range of the first slider 51 (if the height of the first slider 51 is large, the lower end of the first slider 51 is easily swung to the outside of the cavity 11 by the pressure in the cavity 11 only under the fitting between the positioning pin 541 and the positioning pin hole during injection molding), thereby further enhancing the fitting accuracy between the first slider 51 and the cavity 11.

In an embodiment, an L-shaped hook 55 is vertically disposed on a lower end surface of the first slider 51, a hook-shaped end of the L-shaped hook 55 is disposed facing one side of the cavity 11, and an inverted L-shaped hook 56 for hooking the L-shaped hook 55 is disposed at an upper end of the lower die 2 (in fig. 4 to 7, the L-shaped hook 55 is inverted L-shaped, and the inverted L-shaped hook 56 is L-shaped due to a change in a viewing direction). As shown in fig. 8, when the mold is opened, the lower mold 2 moves downward, the inverted L-shaped hook 56 on the lower mold 2 hooks the L-shaped hook 55, and the L-shaped hook 55 gradually separates from the inverted L-shaped hook 56 under the guidance of the guide rail 14; similarly, when the mold is closed, the first slide block 51 moves along the guide rail 14 into the accommodating groove 13 due to the extrusion of the lower mold 2, and the L-shaped hook 55 and the inverted L-shaped hook 56 are gradually hooked together. The advantages are that: when the adhesion force between the first slider 51 and the receiving groove 13 is too large (i.e. the first slider 51 cannot slide under the action of the gravity of the first slider 51 and the elastic force of the spring 521), the inverted L-shaped hook 56 on the lower die 2 can hook the L-shaped hook 55, so as to pull the first slider 51 to slide along the guide rail 14 in a direction away from the cavity 11.

In the embodiment, the L-shaped hook 55 and the inverted L-shaped hook 56 are both provided with an arc-shaped notch 50 for facilitating the hooking and the separation between the two hooks. The arc-shaped notch 50 is shown in fig. 8, which is advantageous in that the hooking and the separation between the L-shaped hook 55 and the inverted L-shaped hook 56 are facilitated.

In an embodiment, the first insert 57 is embedded on the surface of the first slider 51 contacting the receiving groove 13, the outer surface of the first insert 57 is provided with a second oil reservoir 571, and the shape of the second oil reservoir 571 is preferably an X-shaped structure, which has the advantage of improving the smoothness and heat dissipation of the sliding of the first slider 51.

In an embodiment, the side core pulling module 6 includes a second slider 61, a second cylinder 62, and a sliding groove (the sliding groove is drawn in the drawing) located on the upper end surface of the lower mold 2 and configured to accommodate the second slider 61 to slide in a direction away from the mold core 21 along the horizontal direction, the second slider 61 is slidably connected to the sliding groove through the second cylinder 62, and a side surface of the second slider 61 close to the mold core 21 is matched with a side wall of the mold core 21. The advantage is that the second cylinder 62 can control the second slide block 61 to slide in the direction away from the mold core 21 along the horizontal direction, so that the lower mold 2 can be prevented from scratching the outer surface of the molded automobile B-pillar trim when the molded automobile B-pillar trim is separated from the lower mold 2.

In an embodiment, a limiting boss 63 is integrally and upwardly arranged at the upper end of the second slider 61, and a limiting groove 12 for matching with the limiting boss 63 is arranged on the upper die 1 at a position corresponding to the limiting boss 63. The advantages are that: after the mold is closed, the matching precision between the second slide block 61 and the mold core 21 can be improved due to the matching between the limit boss 63 and the limit groove 12.

In an embodiment, the outer surfaces of the second slider 61 and the limit boss 63 are embedded with a second insert (the second insert is not shown in the drawings, and the principle of the second insert is the same as that of the first insert 57), the outer surface of the second insert is provided with a third oil storage groove, and the shape of the third oil storage groove is preferably an X-shaped structure, so that the matching smoothness and heat dissipation performance between the second slider 61 and the sliding groove and between the limit boss 63 and the limit groove 12 are improved.

In an embodiment, a positioning mechanism is further disposed between the upper die 1 and the lower die 2, the positioning mechanism includes a first positioning protrusion 71 integrally connected to four corners of the upper end surface of the lower die 2 and a second positioning protrusion 72 integrally connected to a middle of the upper end surface of the lower die 2, and a first positioning groove 73 for matching with the first positioning protrusion 71 and a second positioning groove 74 for matching with the second positioning protrusion 72 are disposed on the lower end surface of the upper die 1. The advantages are that: the matching precision between the upper die 1 and the lower die 2 is improved by the matching between the first positioning lug 71 and the first positioning groove 73 and the matching between the second positioning lug 72 and the second positioning groove 74.

In an embodiment, a third insert (not shown in the drawings and based on the principle of the first insert) is embedded on the outer surface of the second positioning protrusion 72, and a fourth oil storage groove is formed on the outer surface of the third insert, and the shape of the fourth oil storage groove is preferably an X-shaped structure, which has the advantage of improving the smoothness and heat dissipation of the fit between the second positioning protrusion 72 and the second positioning groove 74.

In an embodiment, the guiding mechanism further includes a plurality of square guide posts 33, the number of the square guide posts 33 is preferably two, two of the square guide posts 33 are vertically installed on the upper end of the lower die 2, and a square guide groove 34 is disposed on the upper die 1 corresponding to the two square guide posts 33. On the premise of matching the circular guide post 31 and the circular guide groove 32, the positioning accuracy between the upper die 1 and the lower die 2 is greatly improved through the matching between the square guide post 33 and the square guide groove 34.

The working principle is as follows: when the mold is closed, the second cylinder 62 pushes the second slide block 61 to slide to the mold core 21 along the chute in place, and then the lower mold 2 moves upwards to close the mold; because the first slider 51 can slide along the guide rail 14 towards the cavity 11 and the lower end surface of the first slider 51 can horizontally slide and match with the upper end surface of the lower die 2, after the upper end surface of the lower die 2 contacts with the lower end surface of the first slider 51, the lower die 2 can push the first slider 51 to slide towards the accommodating groove 13 until the die closing is finished, at this time, the side surface of the first slider 51 matches with the side wall of the cavity 11, the spring 521 is compressed, the L-shaped hook 55 and the inverted L-shaped hook 56 complete the hooking, and the limit boss 63 and the limit groove 12 are precisely matched; gaps for forming the automobile B-pillar trim are formed among the cavity 11, the side surface of the first slide block 51 close to the cavity 11, the core 21, the side surface of the second slide block 61 close to the core 21 and the upper end surface of the ejector rod 42, raw materials are injected into the gaps through the hot runner 22, and the automobile B-pillar trim is formed after cooling; when the mold is opened, the lower mold 2 is moved downwards, and under the action of the inverted L-shaped hook 56, the spring 521 and the self gravity of the first slider 51, the first slider 51 moves along the guide rail 14 in a direction away from the cavity 11 (since the L-shaped hook 55 moves downwards along with the first slider 51, and the inverted L-shaped hook moves downwards, the L-shaped hook 55 and the inverted L-shaped hook 56 are gradually separated), so that the first slider 51 slides away from the cavity 11 before the molded automobile B-pillar trim is separated from the cavity 11, the side surface of the first slider 51 close to the cavity 11 is not in contact with the outer surface of the molded product, and the outer surface of the molded product is prevented from being scratched; after the lower die 2 and the upper die 1 are completely separated, the second cylinder 62 is controlled to drive the second slide block 61 to slide in a direction away from the mold core 21, and then the first cylinder 43 is controlled to drive the bottom plate 41 to push the ejector rod 42, so that the formed product is ejected, in the process, the second slide block 61 slides in the direction of the mold core 21 before the formed product is ejected, so that the side surface of the second slide block 61 close to the mold core 21 is prevented from scratching the formed product when the formed product is ejected. The outer surface of the automobile B-pillar decorative plate produced by the mold is free of scratches, the yield is high, and the market competitiveness of the automobile B-pillar decorative plate is greatly improved.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the technical principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides a module of loosing core to one side, its characterized in that includes last mould (1), is located cavity (11), lower mould (2), first slider (51) on last mould (1) lower terminal surface and is used for holding tank (13) of first slider (51), holding tank (13) are located go up on the lower terminal surface of mould (1) and communicate in cavity (11), first slider (51) can be followed oblique downward direction and to keeping away from cavity (11) direction sliding connection in holding tank (13), but the lower terminal surface horizontal slip of first slider (51) match in the up end of lower mould (2), be close to on first slider (51) the side of cavity (11) with the lateral wall phase-match of cavity (11).

2. The angle core pulling module according to claim 1, wherein the first sliding block (51) is slidably connected to the receiving groove (13) along an obliquely downward direction in a direction away from the cavity (11), that is, a guide rail (14) arranged along the obliquely downward direction in a direction away from the cavity (11) is arranged in the receiving groove (13), and a guide groove for slidably connecting with the guide rail is arranged on the first sliding block (51).

3. The angle core pulling module according to claim 2, wherein a first oil reservoir (141) is provided on a surface of the guide rail (14) contacting the guide groove (511).

4. The angle core pulling module according to claim 1, wherein an elastic member (52) for sliding the first slider (51) in a direction away from the cavity (11) in an obliquely downward direction and a limiting member (53) for preventing the first slider (51) from being separated from the accommodating groove (13) are disposed between the first slider (51) and the accommodating groove (13).

5. The angle core pulling module according to claim 4, wherein the elastic member (52) comprises a plurality of springs (521) arranged along the sliding direction of the first sliding block (51), one end of each spring (521) is mounted at the inner bottom of the corresponding accommodating groove (13), and the other end of each spring (521) is mounted at the upper end face of the first sliding block (51).

6. The angle core pulling module according to claim 4, wherein the limiting member (53) comprises a plurality of limiting blocks (531) installed at the outlet of the accommodating groove (13), and the first slider (51) is provided with limiting sliding grooves (532) along the sliding direction thereof for matching with the limiting blocks (531).

7. The angle core pulling module according to claim 4, wherein a positioning element is further arranged between the first slider (51) and the accommodating groove (13), the positioning element comprises a plurality of positioning pins (541) arranged along the sliding direction of the first slider (51), a plurality of positioning blocks (542) arranged along the sliding direction of the first slider (51), and a plurality of positioning grooves (543) used for being matched with the positioning blocks (542), one end of each positioning pin (541) is mounted at the inner bottom of the accommodating groove (13), and a positioning pin hole used for being movably matched with the other end of each positioning pin (541) is formed in the lower end of the first slider (51); the positioning block (542) is integrally mounted on the side wall of the first slider (51), and the positioning groove (543) is located on the side wall of the accommodating groove (13).

8. The angle core pulling module according to claim 1, wherein an L-shaped hook (55) is vertically arranged on a lower end surface of the first slider (51), a hook-shaped end of the L-shaped hook (55) is arranged in a direction facing one side of the cavity (11), and an inverted L-shaped hook (56) for hooking the L-shaped hook (55) is arranged at an upper end of the lower mold (2).

9. The angle core pulling module as claimed in claim 8, wherein the L-shaped hook (55) and the inverted L-shaped hook (56) are provided with arc-shaped notches (50) for facilitating hooking and separation between the L-shaped hook and the inverted L-shaped hook.

10. The angle module as claimed in claim 1, characterized in that a first insert (57) is embedded on the surface of the first slider (51) in contact with the receiving groove (13), and a second oil reservoir (571) is provided on the outer surface of the first insert (57).

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