CN219191135U - In-mold assembly equipment - Google Patents

Abstract

The utility model discloses in-mold assembly equipment, which relates to the technical field of injection equipment and comprises the following components: the device comprises a base, a fixed die, a sliding block, a guide block, the fixed die, a first linear driving mechanism, a second linear driving mechanism and a carrying assembly, wherein the fixed die is used for injection molding with a movable die to form a first injection molding piece and a second injection molding piece; the first linear driving mechanism and the second linear driving mechanism respectively drive the sliding block and the guide block to move, the sliding block and the guide block are respectively provided with a first strip-shaped hole and a second strip-shaped hole, and the conveying assembly is arranged in the first strip-shaped hole and the second strip-shaped hole in a penetrating mode; the carrying assembly is used for carrying the first injection molding piece or the second injection molding piece so that the first injection molding piece and the second injection molding piece are mutually matched and connected. The sliding block and the guide block are driven to drive the carrying assembly to complete the assembly process of the die, the whole assembly process of the die is simple, the operation process of the assembly equipment of the die is simplified, the structure is simple and compact, and the space occupied by the assembly equipment of the die is saved.

Description

In-mold assembly equipment

Technical Field

The utility model relates to the technical field of injection molding equipment, in particular to in-mold assembly equipment and in-mold assembly equipment.

Background

The in-mold assembly technology refers to a molding technology that two or more polymers are placed in an injection mold through welding, snap fit or incompatible processes, and can obtain a plastic part with more stable quality and performance, the problem of warp deformation or shrinkage out of tolerance commonly existing in secondary operation is avoided, a final part is directly produced from the mold, and the generation link of a semi-finished product is avoided. In the prior art, in-mold assembly technology often adopts in-mold assembly molding technology of co-injection incompatible materials, and a required product is molded at one time through two or more polymer materials without binding force, so that the in-mold assembly technology needs a series of automatic production technology to control equipment to operate, the in-mold assembly equipment is quite complex and huge in volume, a large amount of space is occupied, and the operation of the in-mold assembly equipment is quite complicated.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides the in-mold assembly equipment which can solve the problems of huge volume and complex operation of the traditional in-mold assembly equipment.

An in-mold assembly apparatus according to an embodiment of the present utility model includes:

a base;

the fixed die is connected with the base and is used for injection molding with the movable die to form a first injection molding piece and a second injection molding piece;

the two sliding blocks are respectively arranged on two sides of the fixed die and can be connected to the base in a sliding manner, mounting grooves are formed in the two sliding blocks, first strip-shaped holes are formed in the side walls, close to one side of the fixed die, of the two sliding blocks, the first strip-shaped holes are communicated with the mounting grooves, and the length direction of the first strip-shaped holes is perpendicular to the horizontal direction;

the two guide blocks are respectively arranged in the two mounting grooves in a sliding manner, second strip-shaped holes are formed in the two guide blocks, and the length direction of each second strip-shaped hole forms an included angle with the horizontal direction;

the first linear driving mechanism is arranged on one side of the fixed die and connected with the sliding block so as to drive the sliding block to move along the horizontal direction, and the second linear driving mechanism is arranged on one side of the fixed die and connected with the guide block so as to drive the guide block to move along the horizontal direction;

the carrying assembly is arranged in the first strip-shaped hole and the second strip-shaped hole in a penetrating mode, the sliding block and the guide block can drive the carrying assembly to translate and lift, and the carrying assembly is used for carrying the first injection molding piece or the second injection molding piece so that the first injection molding piece and the second injection molding piece are mutually matched and connected.

Has at least the following beneficial effects:

through driving slider and guide block horizontal migration, make transport subassembly transport and transport first injection molding or second injection molding, just can accomplish first injection molding and second injection molding and mutually support and connect, avoided the warp deformation that secondary operation is often had or shrink out of tolerance problem, and need not personnel's secondary equipment after the in-mould assembly is accomplished, reduced the damage to the finished product because of the human factor in the assembly process, whole in-mould assembly process is simple, has simplified the operation flow of in-mould assembly equipment. The first linear driving mechanism is arranged on one side of the fixed die, the second linear driving mechanism is arranged on one side of the fixed die, the sliding blocks and the guide blocks are arranged on two sides of the fixed die, the whole in-die assembly process can be completed through a simple and compact structure, the size of in-die assembly equipment is reduced, and the space occupied by the in-die assembly equipment is saved.

According to the in-mold assembly equipment provided by the embodiment of the utility model, the first linear driving mechanism is connected with the first pushing plate and the first pushing rod, the first linear driving mechanism is connected with the base, the output end of the first linear driving mechanism is connected with the first pushing plate so as to drive the first pushing plate to move along the horizontal direction, the first pushing plate is connected with one end of the first pushing rod, and the other end of the first pushing rod is connected with the sliding block.

According to the in-mold assembly equipment provided by the embodiment of the utility model, the first linear driving mechanism further comprises a first driving motor, a first screw rod, a guide rod and a first nut seat, wherein the first nut seat is arranged on the first pushing plate, the output end of the first driving motor is in transmission connection with one end of the first screw rod, the other end of the first screw rod is in threaded connection with the first nut seat, a first guide hole is formed in the first pushing plate, the guide rod is connected with the base, and the guide rod is arranged in the first guide hole in a penetrating manner.

According to the in-mold assembly equipment provided by the embodiment of the utility model, the first pushing plate is provided with the avoidance groove, the second linear driving mechanism is connected with the second pushing plate and the second pushing rod, the second linear driving mechanism is connected with the base, the output end of the second linear driving mechanism is connected with the second pushing plate so as to drive the second pushing plate to move along the horizontal direction, the second pushing plate is connected with one end of the second pushing rod, the other end of the second pushing rod is connected with the guide block, the second pushing rod penetrates through the avoidance groove, and the first linear driving mechanism and the second linear driving mechanism are both arranged on the same side of the fixed mold.

According to the in-mold assembly equipment provided by the embodiment of the utility model, the second linear driving mechanism further comprises a second driving motor, a second screw rod and a second nut seat, the second nut seat is arranged on the second pushing plate, the output end of the second driving motor is in transmission connection with one end of the second screw rod, the other end of the second screw rod is in threaded connection with the second nut seat, a second guide hole is formed in the second pushing plate, and the guide rod is arranged in the second guide hole in a penetrating mode.

According to the in-mold assembly equipment provided by the embodiment of the utility model, the carrying assembly comprises the movable rod and the sucker, one end of the movable rod is arranged in the first strip-shaped hole and the second strip-shaped hole in a penetrating manner, the other end of the movable rod is arranged in the other first strip-shaped hole and the other second strip-shaped hole in a penetrating manner, the movable rod can move along the length direction of the first strip-shaped hole and the second strip-shaped hole, the sucker is arranged on one side, close to the fixed mold, of the movable rod, and the sucker is used for adsorbing the first injection molding part or the second injection molding part.

According to the in-mold assembly equipment provided by the embodiment of the utility model, the in-mold assembly equipment further comprises a limiting block and two stop blocks, wherein the two stop blocks are arranged on one side, close to the fixed mold, of the sliding block, a vertical slideway is formed between the two stop blocks, the slideway is communicated with the first strip-shaped hole, the limiting block is arranged on the movable rod, and the limiting block can be slidably arranged in the slideway.

According to the in-mold assembly equipment provided by the embodiment of the utility model, the in-mold assembly equipment further comprises a chute seat, wherein the chute seat is connected with the base, the length direction of a chute on the chute seat is consistent with the sliding direction of the sliding block, and the sliding block is slidably connected with the chute seat.

According to the embodiment of the utility model, the in-mold assembly equipment further comprises a top cover, wherein the top cover is connected with the sliding block, and the top cover is arranged corresponding to the mounting groove.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The utility model is further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a schematic view of an in-mold assembly device according to an embodiment of the present utility model;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a schematic side view of the in-mold assembly device of FIG. 1;

FIG. 4 is a schematic view of the slider, guide block, chute seat and stop block of FIG. 2;

reference numerals:

a base 100; a chute base 110; a guide bar 120; a top cover 130;

a fixed mold 200; a first injection molded part 210; a second injection molded part 220;

a first linear driving mechanism 300; a first pusher plate 310; the avoidance groove 311; a first push lever 320; a slider 330; a mounting groove 331; a first bar-shaped hole 332; a first screw 340;

a second linear driving mechanism 400; a second pusher plate 410; a second push lever 420; a guide block 430; a second stripe hole 431; a second screw 440;

a movable lever 500; suction cup 510; a stopper 520; a stopper 530;

a first thimble 600; second thimble 700.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, plural means two or more. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

Referring to fig. 1 to 4, the in-mold assembly apparatus includes a base 100, a fixed mold 200, a carrying assembly, a first linear driving mechanism 300, a second linear driving mechanism 400, two sliders 330, and two guide blocks 430, the fixed mold 200 being connected to the base 100, the fixed mold 200 being for injection molding with a movable mold to form a first injection molding 210 and a second injection molding 220; the two sliding blocks 330 are respectively arranged at two sides of the fixed die 200 and are slidably connected with the base 100, the two sliding blocks 330 are provided with mounting grooves 331, the side wall of the two sliding blocks 330, which is close to one side of the fixed die 200, is provided with first strip-shaped holes 332, the first strip-shaped holes 332 are communicated with the mounting grooves 331, and the length direction of the first strip-shaped holes 332 is perpendicular to the horizontal direction; the two guide blocks 430 are respectively slidably arranged in the two mounting grooves 331, the two guide blocks 430 are provided with second strip holes 431, and the length direction of each second strip hole 431 forms a certain included angle with the horizontal direction; the first linear driving mechanism 300 is arranged at one side of the fixed mold 200 and connected with the sliding block 330 to drive the sliding block 330 to move along the horizontal direction, and the second linear driving mechanism 400 is arranged at one side of the fixed mold 200 and connected with the guide block 430 to drive the guide block 430 to move along the horizontal direction; the carrying assembly is disposed in the first strip hole 332 and the second strip hole 431 in a penetrating manner, and the sliding block 330 and the guide block 430 can drive the carrying assembly to translate and lift, where the carrying assembly is used for carrying the first injection molding piece 210 or the second injection molding piece 220, so that the first injection molding piece 210 and the second injection molding piece 220 are mutually matched and connected.

It can be appreciated that the first injection molding part 210 and the second injection molding part 220 can be matched and connected by horizontally moving the driving slide block 330 and the guide block 430, so that the problem of warp deformation or shrinkage out of tolerance, which is common in secondary operation, is avoided, and the secondary assembly of personnel is not required after the assembly is completed, so that the damage to finished products caused by human factors in the assembly process is reduced, the whole assembly process is simple, and the operation flow of the assembly equipment in the mould is simplified. The first linear driving mechanism 300 is arranged on one side of the fixed mold 200, the second linear driving mechanism 400 is arranged on one side of the fixed mold 200, and the sliding block 330 and the guide block 430 are arranged on two sides of the fixed mold 200, so that the whole in-mold assembly process can be completed through a simple and compact structure, the size of in-mold assembly equipment is reduced, and the space occupied by the in-mold assembly equipment is saved.

Referring to fig. 1 to 4, the first linear driving mechanism 300 is connected with a first push plate 310 and a first push rod 320, the first linear driving mechanism 300 is connected with the base 100, an output end of the first linear driving mechanism 300 is connected with the first push plate 310 to drive the first push plate 310 to move in a horizontal direction, the first push plate 310 is connected with one end of the first push rod 320, and the other end of the first push rod 320 is connected with the slider 330.

It can be appreciated that the first linear driving mechanism 300 may be a horizontal pushing cylinder, the output end of the horizontal pushing cylinder stretches to drive the first pushing plate 310 to move along the horizontal direction, the first pushing plate 310 drives the first pushing rod 320 and the sliding block 330 to move along the horizontal direction, the handling component is disposed in the first strip hole 332 and the second strip hole 431 in a penetrating manner, and the sliding block 330 is driven to make the handling component translate and lift along the length directions of the first strip hole 332 and the second strip hole 431, so that the handling component connects the first injection molding part 210 and the second injection molding part 220 in a matching manner. The first linear driving mechanism 300 is simple and compact in structure, reduces the volume of the in-mold assembly equipment, and saves the space occupied by the in-mold assembly equipment.

Referring to fig. 1 to 4, the first linear driving mechanism 300 further includes a first driving motor, a first screw rod 340, a guide rod 120, and a first nut seat, the first nut seat is disposed on the first pushing plate 310, an output end of the first driving motor is in transmission connection with one end of the first screw rod 340, the other end of the first screw rod 340 is in threaded connection with the first nut seat, a first guide hole is formed in the first pushing plate 310, the guide rod 120 is connected with the base 100, and the guide rod 120 is disposed in the first guide hole in a penetrating manner. The output end of the first driving motor is in transmission connection with one end of the first screw rod 340 through a coupler. The first drive motor may be a servo motor.

It can be appreciated that the first driving motor drives the first screw rod 340 to rotate, the first screw rod 340 is matched with the first nut seat provided on the first pushing plate 310, so that the first pushing plate 310 moves along the horizontal direction, and the sliding block 330 is driven to move, the first linear driving mechanism 300 can be a servo motor, and the sliding block 330 can be controlled to move more accurately through the transmission of the screw rod and the nut, so that the effect that the carrying assembly can match and connect the first injection molding piece 210 and the second injection molding piece 220 more accurately is achieved; the guide rod 120 is inserted into the first guide hole, so that the first pushing plate 310 can move along the guide rod 120 more smoothly.

Referring to fig. 1 to 4, the first push plate 310 is provided with a avoidance groove 311, the second linear driving mechanism 400 is connected with a second push plate 410 and a second push rod 420, the second linear driving mechanism 400 is connected with the base 100, an output end of the second linear driving mechanism 400 is connected with the second push plate 410 to drive the second push plate 410 to move along a horizontal direction, the second push plate 410 is connected with one end of the second push rod 420, the other end of the second push rod 420 is connected with the guide block 430, the second push rod 420 is arranged in the avoidance groove 311 in a penetrating manner, and the first linear driving mechanism 300 and the second linear driving mechanism 400 are arranged on the same side of the fixed die 200.

It can be understood that the second linear driving mechanism 400 may be a horizontal pushing cylinder, the output end of the horizontal pushing cylinder stretches to drive the second pushing plate 410 to move along the horizontal direction, the second pushing plate 410 drives the second pushing rod 420 and the guiding block 430 to move along the horizontal direction, the carrying assembly passes through the first strip-shaped hole 332 and the second strip-shaped hole 431, and the carrying assembly can generate lifting motion along the length direction of the first strip-shaped hole 332 by driving the guiding block 430; the first linear driving mechanism 300 and the second linear driving mechanism 400 are arranged on the same side of the fixed die 200, and the second pushing rod 420 is arranged in the avoidance groove 311 in a penetrating manner, so that the structure of the in-die assembly equipment is more compact, the volume of the in-die assembly equipment is reduced, and the space occupied by the in-die assembly equipment is saved.

Referring to fig. 1 to 4, the second linear driving mechanism 400 further includes a second driving motor, a second screw rod 440, and a second nut seat, the second nut seat is disposed on the second pushing plate 410, an output end of the second driving motor is in transmission connection with one end of the second screw rod 440, the other end of the second screw rod 440 is in threaded connection with the second nut seat, a second guide hole is formed in the second pushing plate 410, and the guide rod 120 is disposed in the second guide hole in a penetrating manner. The output end of the second driving motor is in transmission connection with one end of the two screw rods 440 through a coupler. The second drive motor may be a servo motor.

It can be appreciated that the second driving motor drives the second screw rod to rotate, the second screw rod 440 is matched with the second nut seat arranged on the second pushing plate 410, so that the first pushing plate 310 moves along the horizontal direction, and the guide block 430 is driven to move, the second linear driving mechanism 400 can be a servo motor, and the guide block 430 can be controlled to move more accurately through the transmission of the screw rod and the nut, so that the effect that the carrying assembly can match and connect the first injection molding piece 210 and the second injection molding piece 220 more accurately is achieved; the guide rod 120 is inserted into the second guide hole, so that the second pushing plate 410 can move along the guide rod 120 more smoothly.

Referring to fig. 1 to 4, the handling assembly includes a movable rod 500 and a suction cup 510, one end of the movable rod 500 is inserted into the first strip hole 332 and the second strip hole 431, the other end of the movable rod 500 is inserted into the other first strip hole 332 and the other second strip hole 431, and can move along the length direction of the first strip hole 332 and the second strip hole 431, the suction cup 510 is disposed on one side of the movable rod 500 close to the fixed mold 200, and the suction cup 510 is used for sucking the first injection molding 210 or the second injection molding 220. It can be appreciated that the suction cup 510 can quickly suck the first injection molding 210 or the second injection molding 220, and the first injection molding 210 and the second injection molding 220 are mutually matched and connected through the movement of the movable rod 500, so that the operation time of the in-mold assembly device is shortened, and the assembly efficiency is improved.

Referring to fig. 1 to 4, the in-mold assembly apparatus further includes a stopper 520 and two stoppers 530, the two stoppers 530 are disposed on one side of the slider 330 near the fixed mold 200, a vertical slide is formed between the two stoppers 530, the slide is communicated with the first bar-shaped hole 332, the stopper 520 is disposed on the movable rod 500, and the stopper 520 is slidably disposed in the slide. It can be understood that the movable rod 500 is provided with the limiting block 520, the limiting block 520 can be slidably arranged in the slideway, the limiting block 520 is limited by the stop block 530 in the translational and lifting process of the movable rod 500, the movable rod 500 is prevented from circumferential rotation in the translational and lifting process, the influence on the subsequent assembly process is caused, and the working stability of the in-mold assembly equipment is improved. Two stoppers 530 are provided on both sliders 330.

Referring to fig. 1 and 2, the in-mold assembly apparatus further includes a chute housing 110, the chute housing 110 is connected to the base 100, a length direction of a chute on the chute housing 110 is identical to a sliding direction of the slider 330, and the slider 330 is slidably connected to the chute housing 110. It can be appreciated that by providing the chute seat 110, the sliding block 330 is slidably connected to the chute on the chute seat 110, so that the sliding block 330 is more stable in the moving process, and the working stability of the in-mold assembly equipment is improved.

Referring to fig. 3, the in-mold assembly apparatus further includes a first ejector pin 600 and a second ejector pin 700, both the first ejector pin 600 and the second ejector pin 700 are disposed on the fixed mold 200, and the first ejector pin 600 and the second ejector pin 700 are used to eject the first injection molding 210 and the second injection molding 220, respectively. It can be appreciated that by providing first ejector pin 600 and second ejector pin 700, first injection molding member 210 and second injection molding member 220 can be separated from the corresponding molds, so that the handling assembly can handle first injection molding member 210 or second injection molding member 220 more easily, and at the same time, it is convenient to take away the integral structure formed by connecting first injection molding member 210 and second injection molding member 220.

Referring to fig. 1, the in-mold assembly apparatus further includes a top cover 130, the top cover 130 being coupled with the slider 330, the top cover 130 being disposed corresponding to the mounting groove 331. It can be appreciated that the top cover 130 is arranged above the mounting groove 331, and the top cover 130 limits the up-and-down movement of the guide block 430, so that the guide block 430 can be effectively prevented from shaking up and down in the process of moving in the mounting groove 331, and the working stability of the in-mold assembly equipment is improved.

An in-mold assembly process is provided, which is implemented by the in-mold assembly device in the above embodiment, and the specific process is as follows:

the first stage: the first injection molding piece 210 and the second injection molding piece 220 are molded, the movable mold is lifted, and the first injection molding piece 210 and the second injection molding piece 220 are exposed;

and a second stage: the first linear driving mechanism 300 drives the sliding block 330 to move along the horizontal direction, the second linear driving mechanism 400 drives the guide block 430 to move along the horizontal direction, the sliding block 330 and the guide block 430 drive the carrying assembly to move to the upper side of the first injection molding piece 210, and the first ejector pin 600 ejects the first injection molding piece 210;

and a third stage: the second linear driving mechanism 400 drives the guide block 430 to move along the horizontal direction, the guide block 430 drives the carrying assembly to descend, the carrying assembly contacts and picks up the first injection molding piece 210, and the first ejector pin 600 resets;

fourth stage: the first linear driving mechanism 300 drives the sliding block 330 to move along the horizontal direction, the sliding block 330 drives the carrying assembly to move, and the carrying assembly carries the first injection molding piece 210 to the upper part of the second injection molding piece 220;

fifth stage: the second linear driving mechanism 400 drives the guide block 430 to move along the horizontal direction, and the guide block 430 drives the carrying assembly and the first injection molding piece 210 to descend, so that the first injection molding piece 210 is matched and mounted on the second injection molding piece 220;

sixth stage: the carrying assembly releases the first injection molding piece 210, the first linear driving mechanism 300 and the second linear driving mechanism 400 respectively drive the sliding block 330 and the guide block 430 to move along the horizontal direction, so that the carrying assembly is reset, the second ejector pin 700 ejects the second injection molding piece 220 and is taken away, and the second ejector pin 700 is reset;

seventh stage: the fixed mold 200 and the movable mold are clamped, and the first stage is entered.

It will be appreciated that by driving the slider 330 and the guide block 430, the handling assembly can be moved along the length direction of the first strip hole 332 and the second strip hole 431, so as to complete the translation and lifting of the handling assembly. When only the sliding block 330 is driven, the carrying assembly translates and lifts under the action of the first strip-shaped hole 332 and the second strip-shaped hole 431; when only the guide block 430 is driven, the first strip hole 332 limits the translation of the handling assembly, and the handling assembly can only be lifted; simultaneously, the sliding block 330 and the guide block 430 are driven, when the speeds of the sliding block 330 and the guide block 430 are consistent, the carrying assembly translates, and when the speed of the guide block 430 is lower than that of the sliding block 330, the carrying assembly translates and lifts. Through driving the sliding block 330 and the guide block 430 to horizontally move, the carrying assembly carries and carries the first injection molding piece 210 or the second injection molding piece 220, so that the first injection molding piece 210 and the second injection molding piece 220 can be matched and connected with each other, the problem of warp deformation or shrinkage out of tolerance caused by secondary operation is avoided, the secondary assembly of personnel is not needed after the assembly of the mold is completed, the damage to finished products caused by human factors in the assembly process is reduced, the whole assembly process of the mold is simple, and the operation flow of the assembly equipment in the mold is simplified.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

Of course, the present utility model is not limited to the above-described embodiments, and those skilled in the art can make equivalent modifications or substitutions without departing from the spirit of the present utility model, and these equivalent modifications or substitutions are included in the scope of the present utility model as defined in the claims.

Claims (10)

1. An in-mold assembly apparatus, comprising:

a base;

the fixed die is connected with the base and is used for injection molding with the movable die to form a first injection molding piece and a second injection molding piece;

the two sliding blocks are respectively arranged on two sides of the fixed die and can be connected to the base in a sliding manner, mounting grooves are formed in the two sliding blocks, first strip-shaped holes are formed in the side walls, close to one side of the fixed die, of the two sliding blocks, the first strip-shaped holes are communicated with the mounting grooves, and the length direction of the first strip-shaped holes is perpendicular to the horizontal direction;

the two guide blocks are respectively arranged in the two mounting grooves in a sliding manner, second strip-shaped holes are formed in the two guide blocks, and the length direction of each second strip-shaped hole forms an included angle with the horizontal direction;

the first linear driving mechanism is arranged on one side of the fixed die and connected with the sliding block so as to drive the sliding block to move along the horizontal direction, and the second linear driving mechanism is arranged on one side of the fixed die and connected with the guide block so as to drive the guide block to move along the horizontal direction;

the carrying assembly is arranged in the first strip-shaped hole and the second strip-shaped hole in a penetrating mode, the sliding block and the guide block can drive the carrying assembly to translate and lift, and the carrying assembly is used for carrying the first injection molding piece or the second injection molding piece so that the first injection molding piece and the second injection molding piece are mutually matched and connected.

2. The in-mold assembly device according to claim 1, wherein: the first linear driving mechanism is connected with a first pushing plate and a first pushing rod, the first linear driving mechanism is connected with the base, the output end of the first linear driving mechanism is connected with the first pushing plate so as to drive the first pushing plate to move along the horizontal direction, the first pushing plate is connected with one end of the first pushing rod, and the other end of the first pushing rod is connected with the sliding block.

3. The in-mold assembly apparatus according to claim 2, wherein: the first linear driving mechanism further comprises a first driving motor, a first screw rod, a guide rod and a first nut seat, wherein the first nut seat is arranged on the first pushing plate, the output end of the first driving motor is in transmission connection with one end of the first screw rod, the other end of the first screw rod is in threaded connection with the first nut seat, a first guide hole is formed in the first pushing plate, the guide rod is connected with the base, and the guide rod penetrates through the first guide hole.

4. An in-mold assembly apparatus according to claim 3, wherein: the first pushing plate is provided with an avoidance groove, the second linear driving mechanism is connected with a second pushing plate and a second pushing rod, the second linear driving mechanism is connected with the base, the output end of the second linear driving mechanism is connected with the second pushing plate so as to drive the second pushing plate to move along the horizontal direction, the second pushing plate is connected with one end of the second pushing rod, the other end of the second pushing rod is connected with the guide block, the second pushing rod penetrates through the avoidance groove, and the first linear driving mechanism and the second linear driving mechanism are all arranged on the same side of the fixed die.

5. The in-mold assembly device according to claim 4, wherein: the second linear driving mechanism further comprises a second driving motor, a second screw rod and a second nut seat, the second nut seat is arranged on the second pushing plate, the output end of the second driving motor is in transmission connection with one end of the second screw rod, the other end of the second screw rod is in threaded connection with the second nut seat, a second guide hole is formed in the second pushing plate, and the guide rod penetrates through the second guide hole.

6. The in-mold assembly device according to claim 1, wherein: the carrying assembly comprises a movable rod and a sucker, one end of the movable rod is arranged in the first strip-shaped hole and the second strip-shaped hole in a penetrating mode, the other end of the movable rod is arranged in the first strip-shaped hole and the second strip-shaped hole in a penetrating mode, the movable rod can move along the length direction of the first strip-shaped hole and the length direction of the second strip-shaped hole, the sucker is arranged on one side, close to the fixed die, of the movable rod, and the sucker is used for adsorbing the first injection molding piece or the second injection molding piece.

7. The in-mold assembly device according to claim 6, wherein: still include stopper and two dogs, two the dog is located the slider is close to one side of cover half, two be formed with vertical slide between the dog, the slide with first strip hole intercommunication, the stopper is located on the movable rod, the stopper can be slided and locate in the slide.

8. The in-mold assembly device according to claim 1, wherein: the sliding block is connected with the base in a sliding way, and the sliding block is connected with the sliding groove seat in a sliding way.

9. The in-mold assembly device according to claim 1, wherein: the injection molding device comprises a fixed die, and is characterized by further comprising a first ejector pin and a second ejector pin, wherein the first ejector pin and the second ejector pin are both arranged on the fixed die and are respectively used for ejecting the first injection molding piece and the second injection molding piece.

10. The in-mold assembly device according to claim 1, wherein: the novel sliding block is characterized by further comprising a top cover, wherein the top cover is connected with the sliding block, and the top cover is correspondingly arranged with the mounting groove.

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