CN116619671A - High-automation injection molding intelligent equipment - Google Patents

Abstract

The invention discloses high-automation injection molding intelligent equipment, which comprises a base, wherein fixed side plates are arranged on two sides of the top of the base, a conveying mechanism is arranged at one end, close to one side, of each fixed side plate, and a buffer guide mechanism is arranged at the middle position of one end, close to one side, of each fixed side plate. According to the invention, the lower die capable of rotating by three hundred and sixty degrees is arranged, so that three main steps of demoulding, cooling and forming can be simultaneously carried out in the lower die, molten liquid enters the flow guide cavity through the injection molding opening, then enters the forming groove through the flow guide cavity, and is formed in the forming groove, meanwhile, a workpiece formed in the forming groove is cooled and formed, the lower die rotates to drive the driving rod to rotate in the guiding chute, and the driving rod ejects a formed part from the forming groove through the ejector rod and the top plate, so that demoulding is completed.

Description

High-automation injection molding intelligent equipment

Technical Field

The invention relates to the technical field of molding equipment, in particular to high-automation injection molding intelligent equipment.

Background

Injection molding is a method of producing shapes for industrial products, which are generally rubber injection molding and plastic injection molding. Injection molding can also be divided into injection molding compression molding and die casting, and an injection molding machine is a main molding device for molding thermoplastic plastics or thermosetting materials into plastic products of various shapes by using a plastic molding die, and injection molding is realized by the injection molding machine and the die.

The current injection molding intelligent device has certain not enough when using:

1. when injection molding is carried out, the upper die and the lower die are generally clamped for injection molding, and then cooled for demolding, and the three groups of steps are sequentially carried out, so that the molding time is the overlapping time of the three main steps, the molding is slow, the requirement of mass production cannot be met, and the work efficiency is reduced.

2. After the molding equipment is molded, the molded part needs to be manually taken out from the equipment, but a large amount of heat remains in the mold due to the fact that the molded part is just molded, scalding is easily caused to the hands of a worker, the time is delayed due to manual taking out, and the labor capacity of the worker is increased.

Disclosure of Invention

The present invention aims to provide a highly automated injection molding intelligent device to solve the above-mentioned related problems in the background art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a high automation injection moulding intelligent device, includes the base, the both sides at base top are provided with fixed curb plate, two sets of fixed curb plate is close to one side's one end each other and is provided with conveying mechanism, two sets of fixed curb plate is close to one side's one end's intermediate position department is provided with buffer guiding mechanism, two sets of fixed curb plate is kept away from one side each other intermediate position department is provided with driving motor, two sets of driving motor's output is provided with the second gear, two sets of fixed curb plate is kept away from one side each other's top rotation and is provided with the swivelling joint, two sets of swivelling joint is provided with first gear in the outside of swivelling joint one side that the swivelling joint is kept away from each other, two sets of swivelling joint is provided with shaping subassembly in one side that the swivelling joint is close to each other, two sets of the top of fixed curb plate back one end is provided with the mounting panel, the inside top of mounting panel is provided with two sets of electric putter, the both sides of mounting panel one end are seted up the connection spout, two sets of the inside slip of connecting spout is provided with the mould, the intermediate position department at last mould top is provided with the injection moulding mouth, the inside intermediate position department of going up the inside is provided with the water conservancy diversion chamber, two sets of being close to one side each other.

Preferably, the buffering guiding mechanism comprises a fixed seat, a baffle, a guide plate, a buffering spring and an arc-shaped sliding rod, wherein the fixed seat is provided with two groups of ends which are respectively positioned at one sides of two groups of fixed side plates and close to each other, the bottom of the fixed seat is provided with the arc-shaped sliding rod, the outer side of the arc-shaped sliding rod is sleeved with the buffering spring, the outer side of the arc-shaped sliding rod is slidably provided with the guide plate, and the two sides of one end of the front surface of the guide plate are provided with the baffle.

Preferably, the shaping subassembly includes lower mould, shaping groove, logical groove, roof, cooling chamber, ejector pin, actuating lever and reset spring, the lower mould is located the one side that two sets of rotatory pipelines are close to each other, lower mould top and bottom are provided with four group's shaping grooves, logical groove has been seted up to the inside top of lower mould and bottom, two sets of it is provided with four groups ejector pins to lead to the inside top slip of groove, four sets of the bottom of ejector pin is provided with the actuating lever, four sets of the top of ejector pin is provided with the roof, the inside of lower mould is provided with the cooling chamber, the intermediate position department at actuating lever top is provided with reset spring.

Preferably, the top of the ejector rod extends to the inside of the forming groove, and the top plate is in sliding fit with the inside of the forming groove.

Preferably, two sides of the driving rod extend out of the inside of the through groove, and two sides of the driving rod extend into the inside of the guide chute and slide mutually.

Preferably, one end of the rotary pipe extends to the inside of the cooling chamber, and the cooling chamber is communicated with the inside of the rotary joint through the rotary pipe.

Preferably, the first gear is located above the second gear, and the first gear and the second gear are meshed with each other.

Preferably, a motor base is arranged at the middle position of one side of the fixed side plate, and the motor base is fixedly connected with the fixed side plate through a corner plate.

Preferably, the edge of lower mould bottom and top has seted up the seal groove, the edge of last mould bottom is provided with the sealing strip, and sealing strip and seal groove looks adaptation each other.

Preferably, one end of each of two sides of the guide plate is provided with a hinge shaft, and the guide plate is located above the conveying mechanism.

Compared with the prior art, the invention provides a high-automation injection molding intelligent device, which comprises the following components

The beneficial effects are that:

1. according to the invention, the lower die capable of rotating by three hundred and sixty degrees is arranged, so that three main steps of demoulding, cooling and forming can be simultaneously carried out in the lower die, during injection molding, the upper die is closely contacted with the top of the lower die, the upper die and the lower die are sealed through the sealing groove and the sealing strip, redundant liquid is prevented from overflowing, molten liquid enters the flow guide cavity through the injection molding opening, enters the forming groove through the flow guide cavity, is formed in the forming groove, is connected with an external water pipe through the rotary joint, and is used for conveying cooling water into the cooling cavity, cooling and forming a workpiece formed in the forming groove, and after a certain period of time, the lower die rotates to drive the driving rod to rotate in the guide chute, so that the driving rod ejects a formed part out of the forming groove through the ejector rod and the top plate, and demoulding is completed.

2. According to the invention, the guide plate capable of swinging is arranged below the lower die, at the moment, when the finished workpiece falls from the inside of the forming groove, the finished workpiece falls on the upper part of the guide plate in advance, the impact force of the falling workpiece is totally applied to the guide plate and can downwards squeeze the guide plate, so that the guide plate slides outside the arc-shaped slide rod, the buffer spring is pushed and squeezed, the impact force is totally applied to the buffer spring, the guide plate can buffer the falling workpiece, and meanwhile, the guide plate can lead the workpiece to totally fall on the conveying mechanism smoothly through the mutual matching of the baffle plates, and the workpiece is conveyed to the next process through the conveying mechanism.

Drawings

FIG. 1 is a front cross-sectional view of the present invention;

FIG. 2 is a side view of a stationary circular plate of the present invention;

FIG. 3 is a schematic view of a buffer guiding mechanism according to the present invention;

FIG. 4 is a schematic view of a molding assembly according to the present invention;

fig. 5 is a side cross-sectional view of a molding assembly of the present invention.

In the figure: 1. a base; 2. a buffer guide mechanism; 201. a fixing seat; 202. a baffle; 203. a guide plate; 204. a buffer spring; 205. an arc slide bar; 3. a molding assembly; 301. a lower die; 302. a forming groove; 303. a through groove; 304. a top plate; 305. a cooling chamber; 306. a push rod; 307. a driving rod; 308. a return spring; 4. a conveying mechanism; 5. fixing the circular plate; 6. rotating the pipe; 7. a first gear; 8. a mounting plate; 9. an electric push rod; 10. an injection molding port; 11. a diversion cavity; 12. the connecting chute; 13. a rotary joint; 14. a driving motor; 15. a second gear; 16. fixing the side plates; 17. a guide chute; 18. and (5) upper die.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-5, the present invention provides the following technical solutions: the utility model provides a high automation injection moulding smart machine, the on-line screen storage device comprises a base 1, the both sides at base 1 top are provided with fixed curb plate 16, the one end that two sets of fixed curb plate 16 are close to one side each other is provided with conveying mechanism 4, the intermediate position department of the one end that two sets of fixed curb plate 16 are close to one side each other is provided with buffer guiding mechanism 2, the intermediate position department that two sets of fixed curb plate 16 are away from one side each other is provided with driving motor 14, the output of two sets of driving motor 14 is provided with second gear 15, the top rotation that two sets of fixed curb plate 16 are away from one side each other is provided with rotatory pipeline 6, the one side that two sets of rotatory pipeline 6 are away from each other is provided with rotary joint 13, the outside of two sets of rotatory pipeline 6 is provided with first gear 7, the one side that two sets of rotatory pipeline 6 are close to each other is provided with shaping subassembly 3, the top of two sets of fixed curb plate 16 back one end is provided with mounting panel 8, the inside top of mounting panel 8 is provided with two sets of electric putter 9, connecting chute 12 has been seted up to the both sides of front one end, the inside slip of two sets of connecting chute 12 is provided with mould 18, the intermediate position department at the top of mould 18 top is provided with injection molding opening 10, the inside position department of mould 18, the inside intermediate position department of two sets of mould 18 is provided with water conservancy diversion chamber 11, the inside is provided with two sets of rotatory pipeline 5 are close to one side each other is provided with the fixed round plate 5.

As a preferable scheme of the present embodiment: the buffer guide mechanism 2 comprises a fixed seat 201, a baffle 202, a guide plate 203, a buffer spring 204 and arc slide bars 205, wherein the fixed seat 201 is provided with two groups of ends which are respectively positioned at one sides of the two groups of fixed side plates 16 and close to each other, the bottoms of the two groups of fixed seats 201 are provided with the arc slide bars 205, the outer sides of the two groups of arc slide bars 205 are sleeved with the buffer spring 204, the outer sides of the two groups of arc slide bars 205 are slidably provided with the guide plate 203, two sides of one ends of the front sides of the two groups of guide plates 203 are provided with the baffle 202, so that falling workpieces can be buffered and guided, and the workpieces are prevented from falling outside.

As a preferable scheme of the present embodiment: the molding assembly 3 comprises a lower die 301, a molding groove 302, a through groove 303, a top plate 304, a cooling cavity 305, ejector rods 306, a driving rod 307 and a reset spring 308, wherein the lower die 301 is positioned on one side of the two groups of rotary pipelines 6, which are close to each other, four groups of molding grooves 302 are formed in the top and the bottom of the lower die 301, the through groove 303 is formed in the top and the bottom of the lower die 301, four groups of ejector rods 306 are slidably arranged in the top of the two groups of the through groove 303, the driving rod 307 is arranged at the bottom of the four groups of ejector rods 306, the top of the four groups of ejector rods 306 is provided with the top plate 304, the cooling cavity 305 is arranged in the lower die 301, the reset spring 308 is arranged at the middle position of the top of the driving rod 307, and molding, cooling and demolding can be automatically performed.

As a preferable scheme of the present embodiment: the top of the ejector rod 306 extends into the forming groove 302, the top plate 304 is slidably matched with the forming groove 302, and the top plate 304 can automatically eject the formed part out of the forming groove 302.

As a preferable scheme of the present embodiment: both sides of the driving lever 307 extend out of the inside of the through groove 303, and both sides of the driving lever 307 extend into the inside of the guide chute 17 and slide each other, so that the driving lever 307 can move up and down when rotating.

As a preferable scheme of the present embodiment: one end of the rotary pipe 6 extends to the inside of the cooling chamber 305, and the cooling chamber 305 communicates with the inside of the rotary joint 13 through the rotary pipe 6, so that the cooling water is not affected when the lower die 301 rotates.

As a preferable scheme of the present embodiment: the first gear 7 is located above the second gear 15, and the first gear 7 and the second gear 15 are meshed with each other.

As a preferable scheme of the present embodiment: the middle position of one side of the fixed side plate 16 is provided with a motor base, and the motor base is fixedly connected with the fixed side plate 16 through a corner plate.

As a preferable scheme of the present embodiment: sealing grooves are formed in the edges of the bottom and the top of the lower die 301, sealing strips are arranged in the edges of the bottom of the upper die 18, and the sealing strips are mutually matched with the sealing grooves.

As a preferable scheme of the present embodiment: one end of the two sides of the guide plate 203 is provided with a hinge shaft, and the guide plate 203 is positioned above the conveying mechanism 4 to guide and buffer the workpiece.

In embodiment 1, as shown in fig. 1-2, when the demolding of the workpiece in the molding groove 302 is completed, the lower die 301 will continue to rotate, and drive the driving rod 307 to slide in the guiding chute 17, the driving rod 307 will move out of the guiding chute 17, so that the driving rod 307 slides outside the fixed circular plate 5, at this time, the lower die 301 continues to rotate, and when the driving rod 307 slides to the vertical groove of the guiding chute 17, the driving rod 307 will be pulled to the bottom in the vertical groove of the guiding chute 17 under the tension of the return spring 308, and meanwhile, the lower die 301 completes the injection molding operation of the next round.

In embodiment 2, as shown in fig. 1 and 3, when demolding is completed, the workpiece falls downward in a free falling manner, the falling workpiece is contacted with the guide plate 203 in advance, the guide plate 203 is pressed downward, the guide plate 203 slides on the outer side of the arc slide rod 205, the buffer spring 204 is pushed and pressed, the impact force is fully applied to the buffer spring 204, the guide plate 203 can buffer the falling workpiece, and meanwhile, the guide plate 203 is matched with the baffle 202, so that the workpiece can be fully and smoothly fallen on the conveying mechanism 4, and the workpiece is conveyed to the next process through the conveying mechanism 4.

Working principle: firstly, when injection molding is performed, at this moment, two groups of rotary joints 13 are connected with an external water pipe, cooling water is conveyed to the inside of a cooling cavity 305 through the action of the rotary joints 13 and a rotary pipeline 6, and water with heat is conveyed out through the other group of rotary pipelines 6 and the rotary joints 13, at this moment, two groups of driving motors 14 are opened to drive a second gear 15 to rotate, the second gear 15 drives a first gear 7 meshed with the second gear to rotate, the first gear 7 drives a lower die 301 to rotationally align through the rotary pipeline 6, at this moment, an electric push rod 9 is opened to push an upper die 18 to slide downwards in the inside of a connecting chute 12, the top of the upper die 18 and the top of the lower die 301 are made to be in contact with each other, and a sealing groove and a sealing strip are made to be mutually inserted and sealed, so that no redundant raw materials overflow from a gap when injection molding is performed on the upper die 18 and the lower die 301.

At this time, the injection molding pipe is connected with the injection molding port 10, the flowing raw material enters the inside of the flow guiding cavity 11 through the injection molding port 10, and flows into the inside of the forming groove 302 through the guiding of the flow guiding cavity 11, meanwhile, external cooling water enters the inside of the cooling cavity 305 through the rotary joint 13 and the rotary pipeline 6 and is fully contacted with the inside of the lower die 301, heat in the lower die 301 and the workpiece is fully absorbed through heat conduction, a large amount of heat is carried, and then water is discharged outside through the other group of the rotary pipelines 6 and the rotary joint 13, so that the workpiece is rapidly formed through cooling of the cooling water.

The formed workpiece is cooled in the forming groove 302, at this time, the upper die 18 is pulled upwards to be far away from the lower die 301 through the electric push rod 9, at this time, the driving motor 14 is turned on again to drive the second gear 15 to rotate, the second gear 15 drives the lower die 301 to rotate through mutual transmission between the rotary pipeline 6 and the first gear 7, at this time, the lower die 301 drives the driving rod 307 to move in the guide chute 17, the driving rod 307 moves to an inclined groove in the vertical groove of the guide chute 17, the driving rod 307 and the rotary pipeline 6 gradually move away from each other while moving, the driving rod 307 continuously moves upwards in the through groove 303 and is close to each other in the forming groove 302, the driving rod 307 pushes the top plate 304 to move through four groups of push rods 306, the top plate 304 pushes the workpiece in the forming groove 302, and when the lower die 301 rotates for one hundred eighty degrees, the workpiece is completely ejected out of the forming groove 302 to complete demoulding.

Finally, it should be noted that the above description is only for illustrating the technical solution of the present invention, and not for limiting the scope of the present invention, and that the simple modification and equivalent substitution of the technical solution of the present invention can be made by those skilled in the art without departing from the spirit and scope of the technical solution of the present invention.

Claims (10)

1. High automation injection moulding intelligent device, including base (1), its characterized in that: the utility model discloses a plastic injection molding machine, which is characterized in that fixed side plates (16) are arranged on two sides of the top of a base (1), one ends of the fixed side plates (16) close to each other are provided with a conveying mechanism (4), two groups of buffer guide mechanisms (2) are arranged at the middle positions of one ends of the fixed side plates (16) close to each other, driving motors (14) are arranged at the middle positions of one ends of the fixed side plates (16) away from each other, a second gear (15) is arranged at the output ends of the driving motors (14), two groups of electric push rods (9) are arranged at the tops of the fixed side plates (16) away from each other, a rotary joint (13) is arranged at one ends of the fixed side plates (16) away from each other, a first gear (7) is arranged at the outer sides of the rotary pipe (6), a forming assembly (3) is arranged at one ends of the rotary pipe (6) close to each other, a mounting plate (8) is arranged at the top of one ends of the back of the fixed side plates (16), two groups of electric push rods (9) are arranged at the top of the inner parts of the fixed side plates (8), a sliding chute (18) is arranged at the inner parts of the two groups of the sliding chute (12) which are connected with one end (12), the middle position inside the upper die (18) is provided with a diversion cavity (11), the top of one side, close to each other, of the two groups of fixed side plates (16) is provided with a fixed circular plate (5), and one side, close to each other, of the two groups of fixed circular plates (5) is provided with two groups of guide sliding grooves (17).

2. The high automation injection molding intelligent device of claim 1, wherein: buffering guiding mechanism (2) are including fixing base (201), baffle (202), deflector (203), buffer spring (204) and arc slide bar (205), fixing base (201) are provided with two sets of one end that are located two sets of fixed curb plates (16) and are close to one side each other, two sets of the bottom of fixing base (201) is provided with arc slide bar (205), two sets of the outside cover of arc slide bar (205) is equipped with buffer spring (204), two sets of the outside slip of arc slide bar (205) is provided with deflector (203), two sets of the both sides of deflector (203) front one end are provided with baffle (202).

3. The high automation injection molding intelligent device of claim 1, wherein: the forming assembly (3) comprises a lower die (301), forming grooves (302), through grooves (303), a top plate (304), a cooling cavity (305), ejector rods (306), driving rods (307) and reset springs (308), wherein the lower die (301) is located on one side, close to each other, of two groups of rotating pipelines (6), four forming grooves (302) are formed in the top and the bottom of the lower die (301), the through grooves (303) are formed in the top and the bottom of the inner portion of the lower die (301), four groups of ejector rods (306) are slidably arranged at the top of the inner portion of the through grooves (303), the driving rods (307) are arranged at the bottom of the four groups of ejector rods (306), the top of the four groups of ejector rods (306) is provided with the top plate (304), the cooling cavity (305) is arranged in the inner portion of the lower die (301), and the reset springs (308) are arranged at the middle position of the top of the driving rods (307).

4. The high automation injection molding intelligent device of claim 3, wherein: the top of the ejector rod (306) extends to the inside of the forming groove (302), and the top plate (304) is in sliding fit with the inside of the forming groove (302).

5. The high automation injection molding intelligent device of claim 3, wherein: the two sides of the driving rod (307) extend out of the inside of the through groove (303), and the two sides of the driving rod (307) extend into the inside of the guide chute (17) and slide mutually.

6. The high automation injection molding intelligent device of claim 1, wherein: one end of the rotary pipeline (6) extends to the inside of the cooling cavity (305), and the cooling cavity (305) is communicated with the inside of the rotary joint (13) through the rotary pipeline (6).

7. The high automation injection molding intelligent device of claim 1, wherein: the first gear (7) is positioned above the second gear (15), and the first gear (7) and the second gear (15) are meshed with each other.

8. The high automation injection molding intelligent device of claim 1, wherein: the motor base is arranged at the middle position of one side of the fixed side plate (16), and the motor base is fixedly connected with the fixed side plate (16) through the angle plate.

9. The high automation injection molding intelligent device of claim 1, wherein: sealing grooves are formed in the edges of the bottom and the top of the lower die (301), sealing strips are arranged at the edges of the bottom of the upper die (18), and the sealing strips are mutually matched with the sealing grooves.

10. The high automation injection molding intelligent device of claim 2, wherein: one end of each of two sides of the guide plate (203) is provided with a hinge shaft, and the guide plate (203) is positioned above the conveying mechanism (4).