CN212528585U - Large-scale servo drive injection molding machine - Google Patents

Abstract

The utility model discloses an injection molding machine technical field's a large-scale servo drive injection molding machine, include: a servo motor; the feeding assembly is arranged on the right end face of the servo motor; the feeding hole is arranged on the left side of the top of the feeding assembly, and the inner cavity of the feeding hole is communicated with the inner cavity of the feeding assembly; the fixed die block assembly is arranged on a discharge port at the right end of the feeding assembly; the movable module assembly is mounted on a demoulding assembly on the right side face of the fixed module assembly, the demoulding assembly is mounted on the movable module assembly, and the demoulding assembly is arranged on the right side of the fixed module assembly; the cylinder, the cylinder is installed the right side middle-end of movable mould block subassembly, the utility model discloses the functioning speed is fast, and the precision of moulding plastics is high, improves production efficiency to can ensure to mould plastics evenly, reduce the formation of bubble.

Description

Large-scale servo drive injection molding machine

Technical Field

The utility model relates to an injection molding machine technical field specifically is a large-scale servo drive injection molding machine.

Background

An injection molding machine is also known as an injection molding machine or an injection machine. It is a main forming equipment for making various shaped plastic products from thermoplastic plastics or thermosetting plastics by using plastic forming mould. The device is divided into a vertical type, a horizontal type and a full-electric type. The injection molding machine can heat the plastic, apply high pressure to the molten plastic, and inject it to fill the mold cavity.

An injection molding machine generally comprises an injection system, a mold closing system, a hydraulic transmission system, an electrical control system, a lubricating system, a heating and cooling system, a safety monitoring system and the like. The heating system is used for heating the charging barrel and the injection nozzle, and the charging barrel of the injection molding machine generally adopts an electric heating ring as a heating device, is arranged outside the charging barrel and is detected by a thermocouple in sections. The heat is conducted through the cylinder wall to provide a heat source for material plasticization; the cooling system is mainly used for cooling the oil temperature, and the oil temperature is controlled because the oil temperature is too high and various faults occur. The other position needing cooling is near the blanking port of the material pipe, so that the raw material is prevented from being melted at the blanking port, and the raw material cannot be blanked normally.

The existing injection molding machine is low in efficiency, low in response speed, low in running speed and large in error, and when the existing injection molding machine conducts large-scale injection molding, due to the fact that the problem of the flow rate of materials easily causes the materials to be not uniform enough in filling in a cavity, bubbles are increased.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a large-scale servo drive injection molding machine to solve the current injection molding machine inefficiency that proposes in the above-mentioned background art, response speed is slow, and the running speed is slow and the error is big, and current injection molding machine is when carrying out large-scale injection molding, because the problem of the velocity of flow of material leads to the material to be not enough even in the intussuseption of die cavity easily, has increased the problem of the formation of bubble.

In order to achieve the above object, the utility model provides a following technical scheme: a large servo drive injection molding machine comprising:

a servo motor;

the feeding assembly is arranged on the right end face of the servo motor;

the feeding hole is arranged on the left side of the top of the feeding assembly, and the inner cavity of the feeding hole is communicated with the inner cavity of the feeding assembly;

the fixed die block assembly is arranged on a discharge port at the right end of the feeding assembly;

the movable module assembly is arranged on the right side surface of the fixed module assembly;

the demolding assembly is arranged on the movable module assembly, and the demolding assembly is arranged on the right side of the fixed module assembly;

the cylinder is installed at the right middle end of the movable module assembly.

Preferably, the feed assembly comprises:

a thermal insulation layer;

the heat conduction layer is arranged in the inner cavity of the heat insulation layer;

the electromagnetic heating pipe is arranged between the heat insulation layer and the heat conduction layer;

the discharge gate, the discharge gate sets up the insulating layer with the right side of heat-conducting layer.

Preferably, the fixed module assembly comprises:

fixing the module body;

two ultrasonic emission heads, two the ultrasonic emission head is installed in tandem the front and back surface middle-end of cover half body, two the ultrasonic emission head is symmetrical.

Preferably, the movable module assembly comprises:

a first mounting plate;

the four guide rods are arranged at the middle end of the left side of the first mounting plate in a rectangular shape;

the push plates are arranged on the outer walls of the four guide rods;

the top plate is arranged on the left side of the push plate and is connected with the four guide rods;

the four push rods are arranged at four corners of the left side of the top plate and are arranged on the inner sides of the four guide rods;

the movable mould block body is arranged at the left ends of the four push rods, and the movable mould block body is connected with the four guide rods.

Preferably, the stripper assembly comprises:

a second mounting plate;

the first ejector rod is arranged at the middle end of the left side of the second mounting plate;

and the second ejector rods are arranged on the left side of the second mounting plate, and the second ejector rods are arranged on the outer side of the first ejector rods.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model has the advantages of high running speed, high injection precision, high production efficiency, even injection molding can be ensured, bubble generation is reduced, a screw rod is installed at the left end output shaft of a servo motor, the screw rod is driven to rotate by the servo motor to convey materials, the materials are conveyed by the servo motor, the conveying speed and the precision of the materials are improved, the production efficiency is effectively improved, a fixed die block body is installed on a discharge port, the materials are conveyed by the servo motor, the materials enter the inner cavity of the fixed die block body through the discharge port, two ultrasonic transmitting heads are installed at the middle ends of the front surface and the rear surface of the fixed die block body in tandem through bolts, the two ultrasonic transmitting heads are symmetrical, ultrasonic waves are transmitted through the ultrasonic transmitting heads, the materials in the inner cavity of the fixed die block body are vibrated through ultrasonic vibration, and the materials can be paved in the inner cavity of the, can ensure the injection molding to be uniform and reduce the generation of bubbles.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the feeding assembly of the present invention;

FIG. 3 is a schematic structural view of the cover half module assembly of the present invention;

FIG. 4 is a schematic structural view of the movable module assembly of the present invention;

fig. 5 is a schematic structural view of the demolding assembly of the present invention.

In the figure: 100 servo motors, 200 feeding assemblies, 210 heat insulation layers, 220 heat conduction layers, 230 electromagnetic heating pipes, 240 discharge ports, 300 feed ports, 400 fixed mold block assemblies, 410 fixed mold block bodies, 420 ultrasonic wave emitting heads, 500 movable mold block assemblies, 510 first mounting plates, 520 guide rods, 530 push plates, 540 top plates, 550 push rods, 560 movable mold block bodies, 600 demolding assemblies, 610 second mounting plates, 620 first push rods, 630 second push rods and 700 air cylinders.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a large-scale servo drive injection molding machine, the functioning speed is fast, and the precision of moulding plastics is high, improves production efficiency to can ensure to mould plastics evenly, reduce the formation of bubble, please refer to figure 1, include: the device comprises a servo motor 100, a feeding assembly 200, a feeding hole 300, a fixed module assembly 400, a movable module assembly 500, a demoulding assembly 600 and an air cylinder 700;

referring to fig. 1 again, a screw is installed on an output shaft at the left end of the servo motor 100, the screw is driven by the servo motor 100 to rotate so as to convey materials, and the materials are conveyed by the servo motor, so that the conveying speed and the precision of the materials are improved, and the production efficiency is effectively improved;

referring to fig. 1-2, a feeding assembly 200 is installed on a right end surface of the servo motor 100, and the feeding assembly 200 includes:

the thermal insulation layer 210 is an asbestos thermal insulation layer;

the heat conduction layer 220 is arranged in the inner cavity of the heat insulation layer 210, and the heat conduction layer 220 is made of aluminum alloy;

the electromagnetic heating pipe 230 is arranged between the heat insulation layer 210 and the heat conduction layer 220, and heat generated by the electromagnetic heating pipe 230 is transferred to the material through the heat conduction layer 220 to heat the material;

the discharge port 240 is arranged on the right side of the heat insulation layer 210 and the heat conduction layer 220;

referring to fig. 1-2 again, the feed inlet 300 is installed at the left side of the top of the heat insulation layer 210, the discharge outlet at the bottom of the feed inlet 300 penetrates through the heat insulation layer 210 and the heat conduction layer 220 and is inserted into the inner cavity of the heat conduction layer 220, the material enters the inner cavity of the heat conduction layer 220 through the feed inlet 300, the material is heated through the electromagnetic heating pipe 230, and the material is conveyed through the servo motor 100;

referring to fig. 1 to 3, the fixed module assembly 400 is installed on the right discharge port of the feeding assembly 200, and the fixed module assembly 400 includes:

the fixed module body 410 is arranged on the discharge port 240, materials are conveyed through the servo motor 100, and the materials enter the inner cavity of the fixed module body 410 through the discharge port 240;

the two ultrasonic transmitting heads 420 are arranged at the middle ends of the front surface and the rear surface of the fixed die block body 410 in tandem through bolts, the two ultrasonic transmitting heads 420 are symmetrical, ultrasonic waves are transmitted through the ultrasonic transmitting heads 420, and materials in the inner cavity of the fixed die block body 410 are vibrated through ultrasonic vibration, so that the materials can be paved in the inner cavity of the fixed die block body 410, the uniform injection molding can be ensured, and the generation of bubbles is reduced;

referring to fig. 1, 3 and 4, the moving module assembly 500 is installed on the right side surface of the fixed module assembly 400, and the moving module assembly 500 includes:

the first installation plate 510 is on the right side of the fixed module body 410, and the first installation plate 510 corresponds to the fixed module body 410;

four guide rods 520 are welded at the middle end of the left side of the first mounting plate 510 in a rectangular shape, and the left ends of the guide rods 520 are installed on the right side surface of the fixed module body 410 through threaded connection;

the push plate 530 is mounted on the outer walls of the four guide rods 520, the four corners of the left side of the push plate 530 are respectively provided with a first mounting hole, the first mounting holes penetrate through the right side of the push plate 530, the four first mounting holes correspond to the four guide rods 520 one by one, the push plate 530 is sleeved on the outer walls of the four guide rods 520 through the first mounting holes, and the push plate 530 can slide on the four guide rods 520;

the top plate 540 is mounted on the left side of the push plate 530 through a bolt, the top plate 540 is connected with the four guide rods 520, second mounting holes are formed in four corners of the left side of the top plate 540, the second mounting holes penetrate through the right side of the top plate 540, the four second mounting holes correspond to the four guide rods 520 one by one, the top plate 540 is sleeved on the outer walls of the four guide rods 520 through the second mounting holes, and the top plate 540 can slide on the four guide rods 520;

four push rods 550 are welded at the four left corners of the top plate 540, and the four push rods 550 are all arranged at the inner sides of the four guide rods 520;

the movable module body 560 is installed at the left ends of the four push rods 550, the movable module body 560 is connected with the four guide rods 520, the four left corners of the movable module body 560 are provided with third installation holes, the third installation holes penetrate through the right side of the movable module body 560, the four third installation holes correspond to the four guide rods 520 one by one, the movable module body 560 is sleeved on the outer walls of the four guide rods 520 through the third installation holes, the movable module body 560 can slide on the four guide rods 520, and the left side surface of the movable module body 560 is welded with the left ends of the four push rods 550;

referring to fig. 1, 4 and 5, the stripper assembly 600 is mounted on the moving module assembly 500, the stripper assembly 600 is on the right side of the fixed module assembly 400, and the stripper assembly 600 includes:

four corners of the left side of the second mounting plate 610 are all provided with fourth mounting holes, the fourth mounting holes penetrate through the right side of the second mounting plate 610, four corners of the left side of the second mounting plate 610 are all provided with fifth mounting holes, the fifth mounting holes penetrate through the right side of the second mounting plate 610, the four fifth mounting holes are all arranged on the inner sides of the four fourth mounting holes, the four fourth mounting holes correspond to the four guide rods 520 one by one, the second mounting plate 610 is sleeved on the outer walls of the four guide rods 520 through the four fourth mounting holes, the second mounting plate 610 is fixedly connected with the four guide rods 520, the four fifth mounting holes correspond to the four push rods 550, the second mounting plate 610 is sleeved on the outer walls of the four push rods 550 through the four fifth mounting holes, the second mounting plate 610 is movably connected with the four push rods 550, and the second mounting plate 610 is arranged between the top plate 540 and the movable module body 560;

the first mandril 620 is welded at the middle end of the left side of the second mounting plate 610;

the plurality of second ejector rods 630 are welded on the left side of the second mounting plate 610, the plurality of second ejector rods 630 are arranged on the outer side of the first ejector rod 620, the movable module body 560 is provided with demolding holes corresponding to the first ejector rod 620 and the plurality of second ejector rods 630, the first ejector rod 620 and the plurality of second ejector rods 630 are inserted into the demolding holes in an inserting mode, and materials after injection molding are pushed out, so that the purpose of demolding is achieved;

referring to fig. 1 and 4, the cylinder 700 is mounted at the right middle end of the first mounting plate 510 by bolts, the left telescopic portion of the cylinder 700 penetrates the first mounting plate 510 and is fixedly connected with the push plate 530, the push plate 530 is pushed to move by the air cylinder 700, the top plate 540 is pushed to move by the push plate 530, the push rod 550 is pushed to move by the top plate 540, the movable module body 560 is pushed to move by the push rod 550, so that the movable mold block body 560 and the fixed mold block body 410 are combined together for injection molding, the push plate 530 is driven to retract by the cylinder 700 after the injection molding is finished, the push plate 530 drives the top plate 540 to retract, the top plate 540 drives the push rod 550 to retract, the push rod 550 drives the movable module body 560 to retract until the movable module body 560 contacts with the first push rod 620 and the second push rod 630, the injection-molded material is pushed out of the cavity on the driven module body 560 by the first ejector pin 620 and the second ejector pin 630.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of such combinations is not exhaustive in the present specification only for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (5)

1. The utility model provides a large-scale servo drive injection molding machine which characterized in that: the method comprises the following steps:

a servo motor (100);

the feeding assembly (200), the feeding assembly (200) is installed on the right end face of the servo motor (100);

the feeding hole (300) is arranged on the left side of the top of the feeding assembly (200), and the inner cavity of the feeding hole (300) is communicated with the inner cavity of the feeding assembly (200);

the fixed die block assembly (400), the fixed die block assembly (400) is installed on a discharge port at the right end of the feeding assembly (200);

the moving module assembly (500), the moving module assembly (500) is installed on the right side surface of the fixed module assembly (400);

the demolding assembly (600), the demolding assembly (600) is installed on the movable module assembly (500), and the demolding assembly (600) is arranged on the right side of the fixed module assembly (400);

the air cylinder (700), the air cylinder (700) is installed at the right side middle end of the movable module component (500).

2. A large servo drive injection molding machine as claimed in claim 1, wherein: the feed assembly (200) comprises:

a thermal insulation layer (210);

a thermally conductive layer (220), the thermally conductive layer (220) disposed within an interior cavity of the thermally insulating layer (210);

an electromagnetic heating pipe (230), the electromagnetic heating pipe (230) being mounted between the insulation layer (210) and the conductive layer (220);

the discharge port (240) is arranged on the right sides of the heat insulation layer (210) and the heat conduction layer (220).

3. A large servo drive injection molding machine as claimed in claim 1, wherein: the fixed module assembly (400) comprises:

a fixed module body (410);

two ultrasonic emission heads (420), two ultrasonic emission heads (420) are installed in tandem in the front and back surface middle-end of cover half body (410), two ultrasonic emission heads (420) are symmetrical.

4. A large servo drive injection molding machine as claimed in claim 1, wherein: the moving module assembly (500) comprises:

a first mounting plate (510);

four guide rods (520), wherein the four guide rods (520) are installed at the middle end of the left side of the first installation plate (510) in a rectangular shape;

the push plates (530), the push plates (530) are installed on the outer walls of the four guide rods (520);

a top plate (540), wherein the top plate (540) is installed at the left side of the push plate (530), and the top plate (540) is connected with the four guide rods (520);

four push rods (550), wherein the four push rods (550) are arranged at the left four corners of the top plate (540), and the four push rods (550) are arranged at the inner sides of the four guide rods (520);

the movable mould block body (560) is installed at the left ends of the four push rods (550), and the movable mould block body (560) is connected with the four guide rods (520).

5. A large servo drive injection molding machine as claimed in claim 1, wherein: the stripper assembly (600) comprises:

a second mounting plate (610);

a first mandril (620), wherein the first mandril (620) is arranged at the middle end of the left side of the second mounting plate (610);

a plurality of second lift pins (630), a plurality of second lift pins (630) being installed at a left side of the second mounting plate (610), a plurality of second lift pins (630) being outside the first lift pins (620).

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