CN116512541B

CN116512541B - Sectional type slider actuating mechanism and injection molding machine

Info

Publication number: CN116512541B
Application number: CN202310806025.XA
Authority: CN
Inventors: 肖成龙; 张传友; 钱烈洪; 兰兴国; 李福�
Original assignee: Hi P Chengdu Precision Plastic Manufacturing Co ltd
Current assignee: Hi P Chengdu Precision Plastic Manufacturing Co ltd
Priority date: 2023-07-03
Filing date: 2023-07-03
Publication date: 2023-08-22
Anticipated expiration: 2043-07-03
Also published as: CN116512541A

Abstract

A sectional type slide block driving mechanism and an injection molding machine relate to the field of injection molding machines, wherein the sectional type slide block driving mechanism comprises a front template and a core-pulling guide rod, the front template is provided with a front mould slide block, and the front mould slide block is provided with an inclined slide hole; the core-pulling guide rod comprises a first guide rod, a second guide rod and a locking mechanism, wherein the second guide rod is in sliding connection with the front template, one end, far away from the first guide rod, of the second guide rod is provided with an inclined guide block matched with the inclined sliding hole, and the locking mechanism is used for interlocking the first guide rod with the second guide rod or unlocking the first guide rod and the second guide rod from each other. The core-pulling guide rod is divided into a first guide rod and a second guide rod, the first guide rod and the second guide rod are mutually locked or unlocked at a preset position through the locking mechanism, after the mold is opened, the second guide rod is positioned in the front mold plate, only the first guide rod is arranged between the front mold plate and the nozzle plate, and the length of the core-pulling guide rod between the front mold plate and the nozzle plate is reduced, so that the problems that the core-pulling guide rod is easy to clamp materials and fracture are solved.

Description

Sectional type slider actuating mechanism and injection molding machine

Technical Field

The application relates to the technical field of injection molding machines, in particular to a sectional type sliding block driving mechanism and an injection molding machine.

Background

With the progress of plastic technology, the requirements of people on appearance modeling, light weight, comfort and the like of plastic products are further improved, and higher requirements are put on design and manufacture of the plastic products. In some molded articles formed by the mold, there is inevitably a parting direction different from the mold parting direction, for example, the articles have lateral holes, lateral grooves, lateral bosses, inclined surfaces or inclined holes, etc., and in addition to the fact that forced demolding can be performed in a very small number of cases, lateral parting and core pulling demolding are generally required to be performed to take out the articles from the mold.

Fig. 1 is a schematic view of a prior art injection molding machine in an open state. Fig. 2 is a schematic structural view of a core pulling guide rod and a front mold slide block in the prior art. As shown in fig. 1 and 2, the conventional three-plate mold includes a rear mold plate 10, a front mold plate 20, and a hot runner plate 30, which are sequentially disposed, the rear mold plate 10 is also called a stationary mold plate, the front mold plate 20 is also called a movable mold plate, and the hot runner plate 30 is also called a top plate. A nozzle plate 40 is arranged between the front template 20 and the hot runner plate 30, and the front template 20, the hot runner plate 30 and the nozzle plate 40 are connected together in a sliding way through guide posts 50. The front mold plate 20 is provided with a front mold slide block 21 in a sliding manner, the water gap plate 40 is fixedly provided with a core pulling guide rod 60 and moves along with the water gap plate 40, the front mold slide block 21 is provided with an inclined slide hole 211, and the end part of the core pulling guide rod 60 is provided with an inclined guide block 621 matched with the inclined slide hole 211. When the mold is opened, the front mold plate 20, the hot runner plate 30 and the nozzle plate 40 are separated from each other, the core pulling guide rod 60 drives the front mold slide block 21 to slide, and the front mold slide block 21 drives the mandrel 22 to move, so that the core pulling action is completed.

However, after the mold is opened, the core-pulling guide rod 60 is located between the nozzle plate 40 and the front mold plate 20, the core-pulling guide rod 60 protrudes from the nozzle plate 40 to be longer, when the material root 70 of the product falls from between the nozzle plate 40 and the front mold plate 20, the material root 70 is extremely easy to fall on the core-pulling guide rod 60, the problem of material clamping can occur, the mold is damaged, and the grabbing of the material root 70 by the manipulator can be influenced. Further, since the front mold slider 21 is generally provided on the side of the front mold plate 20 close to the rear mold plate 10, the length of the core back guide 60 needs to be set relatively long, resulting in weakening of strength and easy breakage during production.

Disclosure of Invention

In order to overcome the defects and shortcomings in the prior art, the application aims to provide a sectional type slide block driving mechanism and an injection molding machine, so as to solve the problems that a core-pulling guide rod in a three-plate die in the prior art is easy to clamp and break.

The aim of the application is achieved by the following technical scheme:

the application provides a sectional type slide block driving mechanism, comprising:

the front die plate is provided with a front die sliding block which is in sliding connection with the front die plate and can slide along the axis direction of the mandrel on the front die plate, and the front die sliding block is provided with an inclined sliding hole;

the core-pulling guide rod comprises a first guide rod, a second guide rod and a locking mechanism, wherein a guide rod sliding hole for installing the second guide rod is formed in the front template, the second guide rod is in sliding connection with the front template and can slide in the guide rod sliding hole along the axial direction of the guide column, one end, away from the first guide rod, of the second guide rod is provided with an inclined guide block matched with the inclined sliding hole, and the locking mechanism is used for locking the first guide rod and the second guide rod or releasing the mutual locking of the first guide rod and the second guide rod;

in the mold closing process, when the first guide rod moves to a preset position along the axial direction of the guide post towards the front mold plate, the locking mechanism locks the first guide rod and the second guide rod, and the second guide rod synchronously moves with the first guide rod and drives the front mold sliding block to positively slide along the axial direction of the mandrel; in the die opening process, the first guide rod moves away from the front die plate along the axial direction of the guide post, the second guide rod moves synchronously with the first guide rod and drives the front die slide block to reversely slide along the axial direction of the mandrel, and when the first guide rod moves to the preset position, the locking mechanism releases the mutual locking of the first guide rod and the second guide rod, and the first guide rod and the second guide rod are mutually separated;

the axial direction of the mandrel is perpendicular to the axial direction of the guide post.

Further, the first guide arm is equipped with first trip towards the one end of second guide arm, locking mechanism includes locking slider, first elastic component and unblock dog, locking slider with second guide arm sliding connection and ability follow on the second guide arm the axis direction of dabber slides, be equipped with on the locking slider with first trip complex second trip, first elastic component has the messenger locking mechanism orientation unblock dog removes elasticity, unblock dog with the front bezel is fixed and with the tip inclined plane cooperation of locking slider.

Further, one end of the first hook facing the second hook is provided with a guide inclined plane, and the guide inclined plane is used for guiding the first hook and the second hook to be buckled with each other; and/or one end of the second hook facing the first hook is provided with a guide inclined plane, and the guide inclined plane is used for guiding the first hook and the second hook to be buckled with each other.

Further, the first elastic piece is arranged on one side, far away from the unlocking stop block, of the locking stop block, one end of the first elastic piece is in contact with the locking stop block, and the other end of the first elastic piece is in contact with the second guide rod.

Further, the second guide rod is provided with a containing cavity for containing the locking slide block, the locking slide block is arranged in the containing cavity and can slide in the containing cavity along the axis direction perpendicular to the guide post, a first opening is formed in one side of the containing cavity, which faces the unlocking stop block, and a second opening is formed in one side, which faces the first guide rod, of the containing cavity.

Further, a reset mechanism is arranged on the front template, and the reset mechanism has a reset force for enabling the second guide rod to slide towards the first guide rod.

Further, the reset mechanism comprises a limit sliding column and a second elastic piece, the limit sliding column is fixed with the front template, the second guide rod is provided with a sliding connection part, the sliding connection part is sleeved on the limit sliding column and can slide along the axis direction of the guide column on the limit sliding column, the limit sliding column is used for limiting the sliding distance of the sliding connection part on the limit sliding column, and the second elastic piece is sleeved on the limit sliding column and is positioned between the sliding connection part and the front template.

Further, the core pulling guide rod comprises a fixing base, wherein the fixing base is provided with a containing hole for containing the first guide rod, and the end part of the first guide rod extends out of the containing hole.

Further, the sectional type slide block driving mechanism further comprises a hot runner plate, a water gap plate and a guide post, wherein the front template, the water gap plate and the hot runner plate are sequentially connected in a sliding manner through the guide post;

the first guide rod is fixed on the hot runner plate and slides on the guide column along the axial direction of the guide column together with the hot runner plate; or the first guide rod is fixed on the water gap plate and slides on the guide column along the axial direction of the guide column together with the water gap plate.

The application also provides an injection molding machine, which comprises the segmented slide block driving mechanism, wherein at least one front mold slide block is arranged on a front mold plate of the injection molding machine, and each front mold slide block is provided with a core pulling guide rod matched with the front mold slide block.

The application has the beneficial effects that: the core-pulling guide rod is divided into a first guide rod and a second guide rod, the second guide rod is arranged in the front template, the first guide rod and the second guide rod are mutually locked or released from being mutually locked through a locking mechanism at a preset position, after the die is opened, the second guide rod is positioned in the front template, and only the first guide rod is arranged between the front template and the water gap plate, so that the length of the core-pulling guide rod between the front template and the water gap plate is reduced, and the problem that the core-pulling guide rod is easy to clamp materials is solved; and after the core-pulling guide rod is divided into a first guide rod and a second guide rod, the length of the first guide rod is shorter than that of the original core-pulling guide rod, so that the problem that the core-pulling guide rod is easy to break is solved.

Drawings

Fig. 1 is a schematic view of a prior art injection molding machine in an open state.

Fig. 2 is a schematic structural view of a core pulling guide rod and a front mold slide block in the prior art.

Fig. 3 is a schematic view of the structure of the injection molding machine in the mold opening state according to the present application.

Fig. 4 is a schematic structural view of the core pulling guide rod and the front mold slide block in the open mold state in the present application.

Fig. 5 is a schematic structural view of the core pulling guide rod and the front mold slide block in the mold closing state in the present application.

Fig. 6 is a schematic perspective view of a first guide bar according to the present application.

Fig. 7 is a schematic structural view of a second guide rod according to the present application.

Fig. 8 is a schematic perspective view of a second guide bar according to the present application.

Fig. 9 is a schematic view of the injection molding machine according to the present application in a mold clamping state.

Fig. 10 is a partially enlarged schematic view at a in fig. 9.

FIG. 11 is a schematic view showing an injection molding machine in a clamped state according to another embodiment of the present application.

In the figure: a rear form 10; front template 20, guide rod slide hole 201, front mold slide block 21, inclined slide hole 211, mandrel 22, reset mechanism 23, limit slide column 231 and second elastic piece 232; a hot runner plate 30; a nozzle plate 40; a guide post 50; the core pulling guide rod 60, the first guide rod 61, the first clamping hook 611, the second guide rod 62, the inclined guide block 621, the accommodating cavity 622, the sliding connection portion 623, the blocking block 624, the locking mechanism 63, the locking slide block 631, the second clamping hook 631a, the first elastic piece 632, the unlocking block 633 and the fixing base 64; root 70.

Detailed Description

In order to further describe the technical means and effects adopted by the application to achieve the preset aim, the following detailed description is given of the specific implementation, structure, characteristics and effects of the sectional type slide driving mechanism and the injection molding machine according to the application by combining the accompanying drawings and the preferred embodiment:

fig. 3 is a schematic view of the structure of the injection molding machine in the mold opening state according to the present application. Fig. 4 is a schematic structural view of the core pulling guide rod and the front mold slide block in the open mold state in the present application. Fig. 5 is a schematic structural view of the core pulling guide rod and the front mold slide block in the mold closing state in the present application. Fig. 6 is a schematic perspective view of a first guide bar according to the present application. Fig. 7 is a schematic structural view of a second guide rod according to the present application. Fig. 8 is a schematic perspective view of a second guide bar according to the present application. Fig. 9 is a schematic view of the injection molding machine according to the present application in a mold clamping state. Fig. 10 is a partially enlarged schematic view at a in fig. 9.

As shown in fig. 3 to 10, the present application provides a segmented slider driving mechanism, which includes:

front mould board 20, front mould board 20 is equipped with front mould slider 21 and dabber 22, and dabber 22 is fixed in one side of front mould slider 21, and front mould slider 21 and front mould board 20 sliding connection can follow the axis direction of dabber 22 on front mould board 20, is equipped with oblique slide hole 211 on the front mould slider 21, and dabber 22 follows front mould slider 21 and slides along the axis direction of dabber 22 on front mould board 20.

The core-pulling guide rod 60, the core-pulling guide rod 60 is parallel to the guide column 50, the core-pulling guide rod 60 comprises a first guide rod 61, a second guide rod 62 and a locking mechanism 63, a guide rod sliding hole 201 for installing the second guide rod 62 is arranged on the front template 20, and the second guide rod 62 is in sliding connection with the front template 20 and can slide along the axis direction of the guide column 50 in the guide rod sliding hole 201. The end of the second guide rod 62 away from the first guide rod 61 is provided with an inclined guide block 621 matched with the inclined slide hole 211, and the second guide rod 62 can drive the front mold slide block 21 to slide in the core pulling direction through the matching of the inclined guide block 621 and the inclined slide hole 211 during mold opening. The lock mechanism 63 is used to lock the first guide bar 61 with the second guide bar 62 or release the mutual lock of the first guide bar 61 and the second guide bar 62, the lock mechanism 63 is used to move together with the second guide bar 62 when the first guide bar 61 is locked with the second guide bar 62, and the lock mechanism 63 releases the mutual lock of the first guide bar 61 and the second guide bar 62 when the first guide bar 61 is unlocked with the second guide bar 62. Wherein, the axis direction of the mandrel 22 and the moving direction of the mandrel 22 are the same direction; the axial direction of the guide post 50 is parallel to the mold closing direction and the mold opening direction. Preferably, the axial direction of the spindle 22 and the axial direction of the guide post 50 are perpendicular to each other.

In the mold closing process, when the first guide bar 61 moves toward the front mold plate 20 in the axial direction of the guide post 50 to a preset position, the locking mechanism 63 locks the first guide bar 61 and the second guide bar 62, and the second guide bar 62 moves synchronously with the first guide bar 61 and drives the front mold slide block 21 to slide forward in the axial direction of the mandrel 22 until the mandrel 22 moves to a proper position; in the mold opening process, the first guide rod 61 moves away from the front mold plate 20 along the axial direction of the guide post 50, the second guide rod 62 moves synchronously with the first guide rod 61 and drives the front mold slide block 21 to slide reversely along the axial direction of the mandrel 22, namely drives the front mold slide block 21 to slide along the core pulling direction, when the first guide rod 61 moves to a preset position, the locking mechanism 63 releases the mutual locking of the first guide rod 61 and the second guide rod 62, the first guide rod 61 and the second guide rod 62 are separated from each other, and the front mold slide block 21 finishes the core pulling action.

According to the application, the core-pulling guide rod 60 is divided into the first guide rod 61 and the second guide rod 62, the second guide rod 62 is arranged in the front mold plate 20, the first guide rod 61 and the second guide rod 62 are mutually locked or mutually locked by the first guide rod 61 and the second guide rod 62 are released at a preset position through the locking mechanism 63, after the mold is opened, as the second guide rod 62 is positioned in the front mold plate 20, only the first guide rod 61 is positioned between the front mold plate 20 and the water gap plate 40, so that the length of the core-pulling guide rod 60 positioned between the front mold plate 20 and the water gap plate 40 is reduced, and the problem that the core-pulling guide rod 60 is easy to clamp materials is solved; and after the core-pulling guide rod 60 is divided into the first guide rod 61 and the second guide rod 62, the length of the first guide rod 61 is shorter than that of the original core-pulling guide rod 60, so that the problem that the core-pulling guide rod 60 is easy to break is solved.

As shown in fig. 4 to 7, in the present embodiment, a first hook 611 is disposed at an end of the first guide rod 61 facing the second guide rod 62. The locking mechanism 63 includes a locking slider 631, a first elastic member 632 and an unlocking stopper 633, the locking slider 631 is provided with a second hook 631a engaged with the first hook 611, and the locking slider 631 is slidably connected to the second guide rod 62 and is capable of sliding on the second guide rod 62 in a direction perpendicular to the axial direction along the guide column 50, so that the first hook 611 and the second hook 631a can be switched between being fastened to each other and being separated from each other. The first elastic member 632 has an elastic force for moving the locking mechanism 63 toward the unlocking stopper 633, that is, the first elastic member 632 has an elastic force for driving the second hook 631a to move toward the direction of engaging with the first hook 611. The unlocking block 633 is fixed to the front mold plate 20 and cooperates with an inclined surface of an end of the locking block 631, i.e., an inclined surface is provided on a side of the unlocking block 633 facing the locking block 631, and/or an inclined surface is provided on a side of the locking block 631 facing the unlocking block 633, and an inclination of the inclined surface is 6 °. In the mold opening process, the locking slide block 631 slides along the axial direction of the guide post 50 along with the second guide rod 62, the unlocking block 633 and the locking slide block 631 perform relative movement, and the unlocking block 633 can drive the second hook 631a to move towards the direction separated from the first hook 611 through the inclined plane cooperation of the unlocking block 633 and the locking slide block 631.

Of course, in other embodiments, the locking mechanism 63 may take other configurations, for example, the end of the first guide rod 61 facing the second guide rod 62 is provided with a buckle, the end of the second guide rod 62 facing the first guide rod 61 is provided with a clamping groove, and the separating force between the buckle and the clamping groove needs to be greater than the driving force required by the front mold slide block 21 during core pulling. Or, the first guide rod 61 is provided with a first magnet towards one end of the second guide rod 62, the second guide rod 62 is provided with a second magnet towards one end of the first guide rod 61, the magnetic attraction force between the first magnet and the second magnet needs to be larger than the driving force required by the front mold slide block 21 during core pulling, and the first magnet and the second magnet can be strong magnets.

Further, a guiding inclined plane is disposed at one end of the first hook 611 facing the second hook 631a, and the guiding inclined plane is used for guiding the first hook 611 and the second hook 631a to be buckled with each other; and/or one end of the second hook 631a facing the first hook 611 is provided with a guiding inclined plane, and the guiding inclined plane is used for guiding the first hook 611 and the second hook 631a to be buckled with each other. In this embodiment, the end of the first hook 611 facing the second hook 631a and the end of the second hook 631a facing the first hook 611 are both provided with guiding inclined planes, and the inclination of the guiding inclined planes is 5 °, so that the first hook 611 and the second hook 631a can be hooked fast and accurately in the mold closing process. In order to ensure the strength of the first hook 611 and the second hook 631a, the thickness of the first hook 611 and the second hook 631a is about 5.0mm, and the ratio of the thickness to the length cannot exceed 1:1; the hook grooves of the first hook 611 and the second hook 631a have a width of about 5.5mm and a ratio of width to height of about 1:1.

Further, the first elastic member 632 is disposed on a side of the locking slider 631 away from the unlocking block 633, one end of the first elastic member 632 is abutted against the locking slider 631, and the other end of the first elastic member 632 is abutted against the second guide rod 62. The second guide rod 62 is further provided with a blocking block 624 (fig. 7), and the other end of the first elastic member 632 is abutted against the blocking block 624 of the second guide rod 62, and the blocking block 624 is detachably connected with the second guide rod 62, so that the first elastic member 632 is convenient to install. The first elastic member 632 is a spring, the first elastic member 632 has a pre-compression amount of 6.0mm before the locking slider 631 does not move, and the first elastic member 632 cannot exceed a maximum compression amount after the locking slider 631 moves by 3.0mm, that is, the first elastic member 632 always maintains a compressed state. Of course, in other embodiments, the first elastic member 632 is disposed on the side of the locking slider 631 facing the unlocking block 633, one end of the first elastic member 632 is connected to the locking slider 631, and the other end of the first elastic member 632 is connected to the second guide rod 62, but the first elastic member 632 is always kept in a stretched state.

Further, the second guide rod 62 is provided with a receiving chamber 622 for receiving the locking slider 631, and the locking slider 631 and the first elastic member 632 are provided in the receiving chamber 622 and can slide in the receiving chamber 622 in a direction perpendicular to the axis of the guide post 50, and the size of the receiving chamber 622 is required to ensure that the locking slider 631 has a sufficient moving space in the second guide rod 62. The accommodating chamber 622 is provided with a first opening on a side facing the unlocking stopper 633, a second opening on a side facing the first guide rod 61, and a third opening on a side facing the stopping stopper 624, the first opening being for the engagement of the locking slider 631 with the inclined surface of the unlocking stopper 633, the second opening being for the insertion of the first guide rod 61 into the accommodating chamber 622, the third opening being for the installation of the first elastic member 632.

As shown in fig. 8 to 10, front mold plate 20 is provided with a return mechanism 23, and return mechanism 23 has a return force for sliding second guide bar 62 toward first guide bar 61, and after the mold is opened, return mechanism 23 prevents second guide bar 62 from sliding in front mold plate 20 when first guide bar 61 and second guide bar 62 are separated from each other.

Further, the reset mechanism 23 includes a limit strut 231 and a second elastic member 232, and the limit strut 231 is fixed to the front mold plate 20. The second guide rod 62 has a sliding connection portion 623, the sliding connection portion 623 is provided with a via hole, the sliding connection portion 623 is sleeved on the limit slide post 231 through the via hole and can slide on the limit slide post 231 along the axial direction of the guide post 50, and the limit slide post 231 is used for limiting the sliding distance of the sliding connection portion 623 on the limit slide post 231. The second elastic member 232 is sleeved on the limit sliding column 231 and is located between the sliding connection portion 623 and the front template 20, so that the second elastic member 232 has an elastic force for driving the second guide rod 62 to slide towards the first guide rod 61, the second elastic member 232 is always in a compressed state, and the second elastic member 232 has a pre-pressing amount of 3-5 m at the beginning. The limit sliding column 231 may be a limit screw, and a nut of the limit screw may limit a sliding distance of the sliding connection portion 623 on the limit sliding column 231. As shown in fig. 10, the sliding distance of the sliding connection portion 623 on the limit strut 231 is B, the B value is greater than the moving distance required by the second guide rod 62 to withdraw the front mold slide 21, and the greater range is 1 to 2mm.

As shown in fig. 3, the segmented slider driving mechanism further includes a hot runner plate 30, a nozzle plate 40 and a guide post 50, where the front mold plate 20, the nozzle plate 40 and the hot runner plate 30 are sequentially slidably connected through the guide post 50, and the nozzle plate 40 and the hot runner plate 30 can slide on the guide post 50, so that the front mold plate 20, the nozzle plate 40 and the hot runner plate 30 can be separated from each other or folded with each other.

In this embodiment, the first guide rod 61 is fixed to the hot runner plate 30 and slides on the guide post 50 along the axial direction of the guide post 50 together with the hot runner plate 30, and a through hole through which the first guide rod 61 passes is required to be provided in the nozzle plate 40. After the mold is opened, since a certain separation distance is also provided between the nozzle plate 40 and the hot runner plate 30, the first guide rod 61 is fixed on the hot runner plate 30, so that the length of the first guide rod 61 between the front mold plate 20 and the nozzle plate 40 can be further reduced, and the risk of material blockage of the core pulling guide rod 60 can be further reduced. Wherein, after the die is opened, the length of the first guide rod 61 exceeding the nozzle plate 40 is within 50.0 m. Of course, in other embodiments, the first guide rod 61 may be fixed to the nozzle plate 40 and slid on the guide post 50 along the axial direction of the guide post 50 together with the nozzle plate 40, and by fixing the first guide rod 61 to the nozzle plate 40, the overall length of the first guide rod 61 may be reduced to reduce the risk of breakage of the first guide rod 61.

Further, as shown in fig. 4 to 6, the loose-core guide bar 60 includes a fixing base 64, the fixing base 64 is provided with a receiving hole for receiving the first guide bar 61, and an end portion of the first guide bar 61 protrudes from the receiving hole. In this embodiment, the fixing base 64 and the first guide rod 61 are fixed on the hot runner plate 30 together, and the fixing base 64 can increase the strength of the first guide rod 61 to reduce the risk of breakage of the first guide rod 61.

The application also provides an injection molding machine comprising a rear mold plate 10 and the segmented slide drive mechanism. As shown in fig. 3, in this embodiment, a front mold block 21 is provided on the front mold plate 20 of the injection molding machine, and therefore, the injection molding machine is provided with only one core back guide 60 that is engaged with the front mold block 21.

Fig. 11 is a schematic view of an injection molding machine in a mold closing state according to another embodiment of the present application, as shown in fig. 11, in other embodiments, a plurality of front mold blocks 21 may be disposed on a front mold plate 20 of the injection molding machine, and each front mold block 21 has a core pulling guide bar 60 matched with the front mold block.

Specifically, during the mold closing process, the front mold plate 20, the gate plate 40, and the hot runner plate 30 are closed together, and the first guide bar 61 moves toward the front mold plate 20 together with the hot runner plate 30. When the first guide bar 61 moves to the preset position toward the front die plate 20 in the axial direction of the guide post 50, the first guide bar 61 slides against the second guide bar 62 in the axial direction of the guide post 50, and at the same time, the locking mechanism 63 locks the first guide bar 61 with the second guide bar 62, and the second guide bar 62 moves synchronously with the first guide bar 61 and drives the front die slide 21 to slide forward in the axial direction of the mandrel 22 until the mandrel 22 moves to the proper position;

during the mold opening process, the front mold plate 20, the nozzle plate 40 and the hot runner plate 30 are separated from each other, and the first guide rod 61 moves away from the front mold plate 20 together with the hot runner plate 30. Since the first guide bar 61 and the second guide bar 62 are in the interlocked locking state at the initial stage of die opening, the second guide bar 62 moves synchronously with the first guide bar 61 and drives the front die slide block 21 to slide reversely along the axial direction of the core shaft 22, i.e., drives the front die slide block 21 to slide along the core pulling direction. When the first guide bar 61 moves to the preset position, the lock mechanism 63 releases the mutual locking of the first guide bar 61 and the second guide bar 62 under the slope cooperation of the unlock stopper 633 and the lock slider 631, and the first guide bar 61 and the second guide bar 62 are separated from each other, at this time, the core pulling operation of the front mold slider 21 is completed.

In this document, terms such as up, down, left, right, front, rear, etc. are defined by the positions of the structures in the drawings and the positions of the structures with respect to each other, for the sake of clarity and convenience in expressing the technical solution. It should be understood that the use of such orientation terms should not limit the scope of the claimed application. It should also be understood that the terms "first" and "second," etc., as used herein, are used merely for distinguishing between names and not for limiting the number and order.

The present application is not limited to the preferred embodiments, but is capable of modification and variation in detail, and other modifications and variations can be made by those skilled in the art without departing from the scope of the present application.

Claims

1. A segmented slide drive mechanism, comprising:

the front mold comprises a front mold plate (20), wherein a front mold sliding block (21) is arranged on the front mold plate (20), the front mold sliding block (21) is in sliding connection with the front mold plate (20) and can slide on the front mold plate (20) along the axis direction of a mandrel (22), and an inclined sliding hole (211) is formed in the front mold sliding block (21);

the core pulling guide rod (60), the core pulling guide rod (60) comprises a first guide rod (61), a second guide rod (62) and a locking mechanism (63), a guide rod sliding hole (201) for installing the second guide rod (62) is formed in the front template (20), the second guide rod (62) is in sliding connection with the front template (20) and can slide along the axis direction of the guide column (50) in the guide rod sliding hole (201), an inclined guide block (621) matched with the inclined sliding hole (211) is formed at one end, far away from the first guide rod (61), of the second guide rod (62), and the locking mechanism (63) is used for locking the first guide rod (61) and the second guide rod (62) in an interlocking mode or unlocking the first guide rod (61) and the second guide rod (62) from each other;

in the mold closing process, when the first guide rod (61) moves to a preset position along the axial direction of the guide post (50) towards the front mold plate (20), the locking mechanism (63) locks the first guide rod (61) and the second guide rod (62) with each other, and the second guide rod (62) moves synchronously with the first guide rod (61) and drives the front mold slide block (21) to positively slide along the axial direction of the mandrel (22); in the die sinking process, the first guide rod (61) moves away from the front die plate (20) along the axial direction of the guide column (50), the second guide rod (62) moves synchronously with the first guide rod (61) and drives the front die sliding block (21) to reversely slide along the axial direction of the mandrel (22), and when the first guide rod (61) moves to the preset position, the locking mechanism (63) releases the mutual locking of the first guide rod (61) and the second guide rod (62), and the first guide rod (61) and the second guide rod (62) are separated from each other;

wherein the axial direction of the mandrel (22) is perpendicular to the axial direction of the guide post (50).

2. The segmented slider driving mechanism according to claim 1, wherein a first hook (611) is provided at an end of the first guide rod (61) facing the second guide rod (62), the locking mechanism (63) comprises a locking slider (631), a first elastic member (632) and an unlocking stopper (633), the locking slider (631) is slidably connected with the second guide rod (62) and is capable of sliding on the second guide rod (62) along an axis direction of the spindle (22), a second hook (631 a) matching with the first hook (611) is provided on the locking slider (631), the first elastic member (632) has an elastic force for moving the locking mechanism (63) toward the unlocking stopper (633), and the unlocking stopper (633) is fixed with the front template (20) and is in slant matching with an end portion of the locking slider (631).

3. The segmented slide driving mechanism according to claim 2, wherein one end of the first hook (611) facing the second hook (631 a) is provided with a guiding inclined plane, and the guiding inclined plane is used for guiding the first hook (611) and the second hook (631 a) to be buckled with each other;

and/or one end of the second hook (631 a) facing the first hook (611) is provided with a guiding inclined plane, and the guiding inclined plane is used for guiding the first hook (611) and the second hook (631 a) to be buckled mutually.

4. The segmented slider driving mechanism according to claim 2, wherein the first elastic member (632) is disposed on a side of the locking slider (631) away from the unlocking stopper (633), one end of the first elastic member (632) abuts against the locking slider (631), and the other end of the first elastic member (632) abuts against the second guide rod (62).

5. The segmented slide drive mechanism according to claim 2, characterized in that the second guide rod (62) is provided with a receiving cavity (622) for receiving the locking slide (631), the locking slide (631) being provided in the receiving cavity (622) and being slidable in the receiving cavity (622) in a direction perpendicular to the axis of the guide post (50), the receiving cavity (622) being provided with a first opening on the side facing the unlocking stop (633) and with a second opening on the side facing the first guide rod (61).

6. The segmented slide driving mechanism according to claim 1, wherein a return mechanism (23) is provided on the front die plate (20), the return mechanism (23) having a return force that slides the second guide bar (62) toward the first guide bar (61).

7. The segmented slide driving mechanism according to claim 6, wherein the reset mechanism (23) comprises a limit slide (231) and a second elastic member (232), the limit slide (231) is fixed with the front template (20), the second guide rod (62) is provided with a sliding connection portion (623), the sliding connection portion (623) is sleeved on the limit slide (231) and can slide on the limit slide (231) along the axis direction of the guide post (50), the limit slide (231) is used for limiting the sliding distance of the sliding connection portion (623) on the limit slide (231), and the second elastic member (232) is sleeved on the limit slide (231) and is located between the sliding connection portion (623) and the front template (20).

8. The segmented slide driving mechanism according to any one of claims 1 to 7, wherein the loose core guide bar (60) includes a fixing base (64), the fixing base (64) is provided with a receiving hole for receiving the first guide bar (61), and an end portion of the first guide bar (61) protrudes from the receiving hole.

9. The segmented slide drive mechanism of any one of claims 1-7, further comprising a hot runner plate (30), a nozzle plate (40) and a guide post (50), wherein the front mold plate (20), the nozzle plate (40) and the hot runner plate (30) are slidingly connected in sequence by the guide post (50);

the first guide rod (61) is fixed on the hot runner plate (30) and slides on the guide column (50) along the axial direction of the guide column (50) together with the hot runner plate (30); alternatively, the first guide rod (61) is fixed to the nozzle plate (40) and slides on the guide post (50) together with the nozzle plate (40) in the axial direction of the guide post (50).

10. Injection molding machine, characterized in that it comprises a segmented slide drive mechanism according to any one of claims 1-9, at least one front mold slide (21) being provided on a front mold plate (20) of the injection molding machine, each front mold slide (21) having a core-pulling guide bar (60) cooperating therewith.