CN214266536U - Electric plasticizing double-stage dynamic injection molding system - Google Patents
Electric plasticizing double-stage dynamic injection molding system Download PDFInfo
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- CN214266536U CN214266536U CN202120144855.7U CN202120144855U CN214266536U CN 214266536 U CN214266536 U CN 214266536U CN 202120144855 U CN202120144855 U CN 202120144855U CN 214266536 U CN214266536 U CN 214266536U
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Abstract
An electric plasticizing double-stage dynamic injection molding system comprises a double-stage injection molding machine, a servo motor, a motor and a mold closing device, wherein the double-stage injection molding machine comprises a plasticizing mechanism and an injection mechanism, the plasticizing mechanism comprises a hopper, a material melting pipeline and a material melting screw rod, the material melting pipeline is provided with a material melting channel, a feeding channel is communicated with the material melting channel, the material melting screw rod is arranged in the material melting channel, the servo motor is in driving connection with the motor, and the motor is in driving connection with the material melting screw rod; the injection mechanism comprises a hydraulic driver, an injection pipeline and an injection rod; an injection channel is arranged in the injection pipeline, an injection rod is arranged in the injection channel, a hydraulic driver is arranged at one end of the injection pipeline, the hydraulic driver is in driving connection with the injection rod, and the injection channel is communicated with the melting channel through a pipeline; an injection molding cavity is arranged in the mold closing device and communicated with the injection channel. This application is rotatory through using servo motor drive motor to drive the material screw rod of melting, compares in traditional oil pump drive, and is more quiet.
Description
Technical Field
The utility model relates to a plastic processing technology field especially relates to an electronic plastify two-step dynamic injection molding system.
Background
An injection molding machine, also known as an injection molding machine or an injection machine, is a main molding device for molding thermoplastic or thermosetting plastic into plastic products of various shapes by using a plastic molding mold. The injection molding machine mainly comprises a feeding mechanism, a charging barrel, a screw, a spray nozzle and other parts. The working principle is that granular materials are added into a charging barrel, the materials are made into a molten state through the rotation of a screw and the heating of the outer wall of the charging barrel, then a machine carries out die assembly and the forward movement of an injection seat to enable a charging barrel injection nozzle to be attached to a glue inlet of a die, then pressure oil is introduced into an injection cylinder to enable the screw to be pushed forward, so that the molten materials are injected into the closed die with lower temperature at high pressure and high speed, the cooling is kept after a certain time and pressure, the die is solidified and formed, and then the die can be opened to take out a product.
Often adopt hydraulic cylinder to advance the propulsive pressure source as the screw rod among the prior art, however, traditional oil pump is the linear type, and thrust is invariable, can't adjust, even meet the barrier still can advance, causes the damage of helical push rod easily.
SUMMERY OF THE UTILITY MODEL
In view of the above, there is a need for an electric plasticizing dual-stage dynamic injection molding system.
An electric plasticizing double-stage dynamic injection molding system comprises a double-stage injection molding machine, a servo motor, a motor and a mold closing device, wherein the double-stage injection molding machine comprises a plasticizing mechanism and an injection mechanism, the plasticizing mechanism comprises a hopper, a material melting pipeline and a material melting screw rod, the hopper is provided with a feeding channel, the material melting pipeline is internally provided with a material melting channel, the feeding channel is communicated with the material melting channel, the material melting screw rod is arranged in the material melting channel, the servo motor is in driving connection with the motor, and the motor is in driving connection with the material melting screw rod; the injection mechanism comprises a hydraulic driver, an injection pipeline and an injection rod; an injection channel is arranged in the injection pipeline, the injection rod is arranged in the injection channel, the hydraulic driver is arranged at one end of the injection pipeline, the hydraulic driver is in driving connection with the injection rod, and the injection channel is communicated with the melting channel through a pipeline; the mold closing device is arranged close to the double-stage injection molding machine, an injection molding cavity is arranged in the mold closing device, and the injection molding cavity is communicated with the injection channel.
In one embodiment, the side wall of the feed channel is provided with a heating device.
In one embodiment, a heat conducting cavity is formed in the side wall of the melting channel, and a heating and heat insulating device is arranged in the heat conducting cavity.
In one embodiment, the apparatus further comprises a first valve disposed in the feed channel.
In one embodiment, the melting device further comprises a second valve, and the second valve is arranged on a pipeline of the injection channel communicated with the melting channel.
In one embodiment, the hopper is arranged above the melting pipeline, and the hopper is detachably connected with the melting pipeline.
In one embodiment, the hopper is in threaded engagement with the melt conduit.
In one embodiment, an agitator is provided on the hopper.
In one embodiment, the stirrer comprises a motor, a roller shaft and a stirring blade, the motor is arranged on the hopper, the roller shaft is arranged in the feeding channel, the motor is in driving connection with the roller shaft, and the stirring blade is fixed on the roller shaft.
In one embodiment, the melt conduit is disposed parallel to the injection conduit.
The utility model has the advantages that: the material melting screw is driven to rotate by the servo motor driving motor, compared with the traditional oil pump driving, the material melting screw is quieter, the pressure can be detected according to the current of the servo motor, the blockage of a plasticizing channel caused by an obstacle is avoided, and the damage to the screw is avoided; and the plasticizing mechanism is used for plasticizing the plastic granules into molten materials, and the injection mechanism is used for injecting the molten materials into the die assembly device, so that the independent operation of plasticizing and injection is realized. And the detention time of the melting material in the machine barrel can be prolonged, and the uniformity of material mixing and plasticizing is improved.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.
Fig. 1 is a schematic structural diagram of an electric plasticizing dual-stage dynamic injection molding system according to an embodiment.
Reference numerals:
10. an electric plasticizing double-stage dynamic injection molding system; 100. a double-stage injection molding machine; 200. a servo motor; 300. a motor; 400. a mold clamping device; 110. a plasticizing mechanism; 120. an injection mechanism; 111. a hopper; 112. a material melting pipeline; 113. a material melting screw rod; 1121. a material melting channel; 121. a hydraulic drive; 122. an injection conduit; 123. an injection rod; 1221. an injection channel; 401. and (5) an injection molding cavity.
Detailed Description
In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.
It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.
Referring to fig. 1, an electric plasticizing dual-stage dynamic injection molding system 10 includes a dual-stage injection molding machine 100, a servo motor 200, a motor 300, and a mold clamping device 400, where the dual-stage injection molding machine 100 includes a plasticizing mechanism 110 and an injection mechanism 120, the plasticizing mechanism 110 includes a hopper 111, a melt pipe 112, and a melt screw 113, the hopper 111 is provided with a feeding channel, the melt pipe 112 is internally provided with a melt channel 1121, the feeding channel is communicated with the melt channel 1121, the melt screw 113 is disposed in the melt channel 1121, the servo motor 200 is in driving connection with the motor 300, and the motor 300 is in driving connection with the melt screw 113; the injection mechanism 120 comprises a hydraulic driver 121, an injection pipeline 122 and an injection rod 123; an injection channel 1221 is arranged in the injection pipeline 122, the injection rod 123 is arranged in the injection channel 1221, the hydraulic driver 121 is arranged at one end of the injection pipeline 122, the hydraulic driver 121 is in driving connection with the injection rod 123, and the injection channel 1221 is communicated with the melt channel 1121 through a pipeline; the mold clamping device 400 is arranged adjacent to the two-stage injection molding machine 100, an injection molding cavity 401 is arranged in the mold clamping device 400, and the injection molding cavity 401 is communicated with the injection channel 1221.
Specifically, the plastic granules are fed from the hopper 111, enter the feeding channel, and then enter the melting channel 1121, the plastic granules can be fully preheated in the feeding channel, and can be more easily plasticized after entering the melting channel 1121, the servo motor 200 drives the motor 300 to rotate, so as to control the rotation of the melting screw 113, when the melting screw 113 rotates, the solid plastic raw material enters the screw groove of the feeding screw from the hopper 111, and generates a shearing effect with the melting box body due to the high-speed rotation of the screw, so that the plastic raw material is mixed and conveyed along the screw groove, and the solid plastic raw material is heated by the electric heating sheet outside the melting channel 112 and the shearing heat generated by the screw, so that the temperature inside the melting channel 1121 is raised to be melted into a molten material; the melt enters the injection passage 1221 from the melt passage 1121. The hydraulic driver 121 may be a hydraulic cylinder, which is installed at the left end of the injection pipe 122 and drives the injection rod 123 to reciprocate linearly in the injection pipe 122, and the moving injection rod 123 pushes the melt in the injection pipe 122 into the injection cavity 401. The injection rod 123 is linearly reciprocated to continuously push the melt in the injection pipe 122 into the mold clamping device 400 to mold the product, and the structure is simple and effective.
Because the servo motor 200 is used for driving the motor 300 and further driving the melting screw 113 to rotate, compared with the traditional oil pump driving, the oil pump driving device is quieter, the pressure can be detected according to the current of the servo motor 200, when the detected pressure is greater than the preset pressure, the servo motor 200 can stop moving in time, so that the screw stops, the blockage of a plasticizing channel caused by an obstacle is avoided, and the damage to the screw is avoided. And, for traditional plastify with mould plastics and go on in same passageway, this application will melt the material and separately go on with moulding plastics, can effectively raise the efficiency.
In addition, compared with a hydraulic oil cylinder, the servo control technology can be more suitable for accurate process control, the output torque can be adjusted in real time according to the process control requirement, and the low-frequency torque is kept to meet the process requirement while the rotating speed is changed. In addition, the rotor in the servo motor 200 is a permanent magnet made of rare earth materials, and the rotary operation can be realized only by inputting a power supply to enable the stator coil to generate a magnetic field, so that the energy consumption of the rotor is reduced, and the operation function of the synchronous motor is realized. Therefore, the servo control saves energy, has high response speed, good control precision, large low-frequency moment, high energy conversion efficiency of the motor, small loss and higher power saving rate, and the power saving rate of the system can reach more than percent. In addition, the servo motor 200 has an advantage of low noise, and can effectively reduce the contrast of driving. In addition, because servo motor 200 response speed is fast, when servo motor 200 is in the drive process, meets the barrier in the oil pump propulsion process, for example, there is the foreign matter in the plastifying pipeline, leads to the oil pump to impel the difficulty or needs great drive power drive and lead to servo motor 200's drive voltage to rise, the controller can in time control servo motor 200 and stop work, avoids the screw rod to damage.
In order to be able to preheat the plastic pellets in the feed channel, in one embodiment the feed channel is provided with heating means on its side walls.
Specifically, the material of feedstock channel's lateral wall is heat conduction metal material, be provided with the heating chamber in feedstock channel's the lateral wall, the chamber wall in heating chamber is provided with a plurality of capillaries, and is a plurality of the capillary distribute in feedstock channel's lateral wall, the heating chamber reaches the capillary intussuseption is filled with the heat-conducting agent, heating device set up in heat the intracavity, heating device is heater strip or heating rod, the heater strip or the heating rod is the heliciform setting, in order to increase the heater strip or the heating rod with the area of contact of heat-conducting agent, through right the heating heat preservation device is switched on, makes heating heat preservation device generates heat, makes again the heat-conducting agent can heat up, and then, the heat-conducting agent passes through the temperature feedstock channel's lateral wall direction plastics for the plastic pellet intensifies softly.
In order to increase the melting speed of the plastic granules in the melting channel 1121, in one embodiment, a heat conducting cavity is formed in a side wall of the melting channel 1121, and a heating and heat insulating device is disposed in the heat conducting cavity. Specifically, the heating and heat-insulating device keeps a high-temperature and constant-temperature environment in the melt channel 1121, so that plastic granules can be rapidly changed into a molten state, the molten plastic is prevented from being cooled, and the injection molding quality is ensured.
In one embodiment, further comprising a first valve disposed within the feed channel.
Specifically, after the plastic particles enter the feeding channel from the feeding hopper 111, the first valve blocks the feeding channel, and meanwhile, the first valve can prevent high-temperature air in the melting channel 1121 from flowing out of the feeding channel, so that dissipation of high temperature in the melting channel 1121 can be reduced; and the plastic particles in the feeding channel above the first valve can be heated by the heating device in the side wall of the feeding channel for a long time, so that the plastic particles to be plasticized can be fully heated. In order to adjust the blanking speed, the inner diameter of the feeding channel can be increased or decreased by adjusting the opening degree of the first valve, that is, the throughput of the feeding channel is enlarged by increasing the opening degree of the first valve, the throughput of the feeding channel is decreased by decreasing the opening degree of the first valve, and the blanking speed of the plastic granules is adjusted.
In order to facilitate the adjustment of the injection rate, in one embodiment, a second valve is further included, and the second valve is disposed on a pipe of the injection passage 1221 communicating with the melt passage 1121.
Compared with the prior art, the plasticizing mechanism 110 and the injection mechanism 120 of the electric plasticizing double-stage dynamic injection molding system 10 provided by the application are connected through the second valve, that is, the conduction of the plasticizing mechanism 110 and the injection mechanism 120 can be respectively realized through the second valve, so that the independent operation of plasticizing and injection is realized. Because the plasticization and the injection do not interfere with each other, the plasticization does not occupy the molding period, thereby not only improving the plasticization quality but also improving the plasticization capacity. And the detention time of the melting material in the machine barrel can be prolonged, and the uniformity of material mixing and plasticizing is improved. And, because the plasticizing time can be properly prolonged, enough time for realizing low-temperature plasticizing can be provided, and the probability that the raw material can be subjected to sudden temperature rise and thermal decomposition caused by excessive shearing is reduced.
In addition, the throughput of the injection molding channel is adjusted by adjusting the opening degree of the second valve, and further, the throughput of the plastic from the melt channel 1121 to the injection channel 1221 in unit time is adjusted, the time for cooling and molding plastic granules of different materials from a molten state is different, and the injection molding speed is adjusted correspondingly by corresponding to the plastic granules of different materials, so that the injection molding quality is improved. Further, by closing the second valve, the melting screw 113 is repeatedly rotated forward and backward, so that the plastic granules in the melting channel 1121 can be sufficiently melted.
It should be noted that the melt pipe 112 is generally tubular, when the first valve and the second valve are closed simultaneously, since the plastic in the melt channel 1121 is extruded by the melt screw 113 to the end close to the injection channel during injection molding, the plastic close to the end of the injection channel is pulled to the end away from the injection channel by rotating the melt screw 113 in the direction opposite to the injection molding direction, since the melt screw 113 extends from the end away from the injection channel to the end close to the injection channel, the melt screw 113 is at a distance from the side wall of the box body of the melt pipe 112 where the feeding channel is disposed, the plastic between the melt screw 113 and the melt pipe 112 cannot be pulled to the end away from the injection channel by the melt screw 113, and since the first valve is closed, the injection channel is not continuously fed, therefore, the plastic is difficult to be extruded to the end far away from the injection channel by the melt screw 113, and then the plastic inside the melt channel 1121 is split into two parts respectively located at the two ends of the screw from the whole body by the reverse rotation of the melt screw 113, but the plastic at the end far away from the injection channel cannot be tightly pressed against the side wall of the melt channel 1121, so that the space between the two parts of plastic in the melt channel 1121 appears in a vacuum state by the reverse rotation of the melt screw 113, and when the first valve is opened, the plastic granules inside the injection channel can rapidly enter the melt channel 1121, thereby increasing the blanking speed.
Since the plastic pellets have a plurality of colors, a separate hopper 111 is often used for each color of plastic pellets, and in order to facilitate replacement of the hopper 111, in one embodiment, the hopper 111 is disposed above the melting pipe 112, and the hopper 111 is detachably connected to the melting pipe 112. In order to facilitate quick disassembly of the hopper 111, in the embodiment, the hopper 111 is screwed with the melting pipe 112.
In order to increase the feeding speed of the plastic pellets, in one embodiment, a stirrer is provided on the hopper 111. Specifically, the stirrer stirs in the hopper 111, so that plastic pellets can be rapidly fed. In this embodiment, the agitator includes motor, roller and stirring vane, the motor set up in on the hopper 111, the roller set up in the feedstock channel, the motor with the roller drive is connected, stirring vane is fixed in on the roller. That is, the motor drives the roller rotates, and then drives epaxial the stirring vane rotates, makes the plastic pellet in the hopper 111 keeps the flow state, avoids feed channel blocks up, in order to promote stirring efficiency, stirring vane's quantity is a plurality of, and is a plurality of stirring vane interval sets up, and is a plurality of stirring vane sets up towards different directions respectively, for further promotion stirring efficiency, stirring vane is crooked circular arc blade, compares in straight stirring vane, and circular arc blade can have more area of contact with the plastic pellet, promotes stirring efficiency greatly.
In one embodiment, the melt conduit 112 is disposed parallel to the injection conduit 122. Specifically, the melt plasticized by the plasticizing mechanism 110 vertically flows into the injection mechanism 120, and the vertical flow of the melt effectively shortens the time for the melt to flow from the plasticizing mechanism 110 into the injection mechanism 120 under the action of gravity, so that the problems of non-uniformity and bubble compression caused by temperature difference in the plasticizing process can be reduced, and the quality of subsequent finished products is effectively improved. The melting material pipeline 112 is horizontally arranged, so that the horizontal pushing and injecting of the melting material is more convenient for the injection operation of the injection mechanism 120, and the injection efficiency is more effectively improved. The whole machine is simple in mechanism, the plasticizing capacity and the plasticizing quality can be improved simultaneously, and the requirements of high speed and high efficiency are met.
In order to melt the materials in the material melting pipeline in stages, in one embodiment, the material melting pipeline is sequentially connected with a plurality of hoppers along the conveying direction of the material melting screw, the hoppers are respectively provided with a feeding channel, and the feeding channels are respectively communicated with the material melting channel, that is, in the process of feeding and melting the materials by the material melting screw, because the optimal plasticizing opportunities of different types of plastics are different, the different types of plastics can respectively enter the material melting channel in the corresponding hoppers, contact with different positions of the material melting screw, and are mixed and melted with other types of plastics, so that the modified plastics can be prepared.
In order to be able to perform targeted plasticization on different types of plastics, in this embodiment, the melting screw is a single cylinder with a plurality of different intervals on the surface and with a spiral groove cut on the outer surface or a cone with a conical spiral groove cut on the outer surface; in another embodiment, the melting screw comprises a plurality of cylinders with spiral grooves cut on the outer surfaces or cones with conical spiral grooves cut on the outer surfaces, the cylinders or the cones are connected together in sequence, the intervals of the spiral grooves on the surfaces of the cylinders or the cones are different, and each cylinder or cone is arranged corresponding to the outlet of one feeding channel; specifically, when the melting screw rotates, the heat generated by the plastic particles in the spiral grooves with different intervals on the surface and the shearing effect generated by the side wall of the melting channel are different, so that different types of plastics can be specifically plasticized.
In order to fully mix a plurality of different plastic granules, in another embodiment, the melting screw comprises a rotating roller and a plurality of first stirring protrusions arranged on the surface of the rotating roller, the plurality of first stirring protrusions are respectively arranged around the axis of the rotating roller, the plurality of first stirring protrusions are arranged at intervals, and the cross sections of the plurality of first stirring protrusions are respectively perpendicular to the axis of the rotating roller; specifically, under the rotation of the rotating roller, the first stirring protrusion breaks up the mixed plastic granules, so that a plurality of different plastic granules are sufficiently mixed. Furthermore, in order to enhance the stirring force and avoid the caking phenomenon during the melting of various plastics, a plurality of second stirring bulges are fixed on the cavity wall of the melting channel and are arranged around the rotating roller; the first stirring bulges and the second stirring bulges are arranged in a staggered mode.
In order to ensure that different types of plastic granules can be fully mixed in the blanking process of the hopper, the plastic granule blanking device further comprises a mixing device, the mixing device is used for mixing different types of plastic granules together, in one embodiment, the mixing device comprises an end cover, a speed reducing motor, a rotating shaft, a first motor, a second motor, a first mixing screw and a second mixing screw, the end cover covers the opening of the hopper, the end cover is provided with a plurality of feed inlets, the feed inlets are respectively communicated with the feed channel, the end cover is further provided with a connecting hole, the speed reducing motor is arranged on the end cover, the speed reducing motor is in driving connection with the rotating shaft through an output shaft, the output shaft penetrates through the connecting hole, the rotating shaft is horizontally arranged in the feed channel, and the output shaft is connected with the middle part of the rotating shaft, the first motor and the second motor are connected with the two ends of the rotating shaft respectively, the first motor is in driving connection with the first mixing screw, and the second motor is in driving connection with the second mixing screw. Specifically, multiple plastic granules get into from a plurality of feed inlets, gear motor drive the axis of rotation is rotatory, first motor drive first mixing screw is rotatory, second motor drive the second mixing screw is rotatory, and multiple plastic granules are in mould plastics the passageway in by first mixing screw reaches the stirring of second mixing screw, just first mixing screw with the second mixing screw also can stir the plastic granules on its next door, and stirring effect is good. Due to the characteristic of large upper part and small lower part of the hopper, the feeding channel is large upper part and small lower part, the first mixing screw rod and the second mixing screw rod are placed in a V shape, the length of the first mixing screw rod is larger than that of the second mixing screw rod, namely, the first mixing screw rod can stir plastic particles with deep depth.
In another embodiment, the mixing device includes an end cover, a driving motor, and a feeding screw, the end cover is provided with a plurality of feeding ports, the plurality of feeding ports are respectively communicated with the feeding channel, the center of the end cover is further provided with a connecting hole, the driving motor is arranged on the end cover, the feeding screw is arranged in the feeding channel, one end of the feeding screw passes through the connecting hole and is connected with the driving motor, and the driving motor is used for driving the feeding screw to rotate; the feeding screw rod is close to the one end of end cover is connected with the stirring frame, the stirring frame includes two parallel arrangement's connecting rod and stirring piece, two the one end of connecting rod respectively with the stirring piece is connected, two the other end of connecting rod respectively with the stirring piece is connected, the stirring piece is on a parallel with the lateral wall setting of hopper. In this embodiment, the quantity of agitator frame is a plurality of, and is a plurality of agitator frame is followed feed screw is close to the one end of end cover is toward keeping away from the one end of end cover sets gradually.
The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.
The above embodiments are only intended to illustrate some embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.
Claims (10)
1. An electric plasticizing double-stage dynamic injection molding system is characterized by comprising a double-stage injection molding machine, a servo motor, a motor and a mold closing device,
the double-stage injection molding machine comprises a plasticizing mechanism and an injection mechanism, wherein the plasticizing mechanism comprises a hopper, a material melting pipeline and a material melting screw rod, the hopper is provided with a feeding channel, the material melting pipeline is internally provided with a material melting channel, the feeding channel is communicated with the material melting channel, the material melting screw rod is arranged in the material melting channel, the servo motor is in driving connection with the motor, and the motor is in driving connection with the material melting screw rod;
the injection mechanism comprises a hydraulic driver, an injection pipeline and an injection rod; an injection channel is arranged in the injection pipeline, the injection rod is arranged in the injection channel, the hydraulic driver is arranged at one end of the injection pipeline, the hydraulic driver is in driving connection with the injection rod, and the injection channel is communicated with the melting channel through a pipeline;
the mold closing device is arranged close to the double-stage injection molding machine, an injection molding cavity is arranged in the mold closing device, and the injection molding cavity is communicated with the injection channel.
2. An electro-dynamic plasticating two-stage injection molding system as defined in claim 1 wherein said feed channel has heating means disposed on the side walls thereof.
3. The electric plasticizing dual-stage dynamic injection molding system of claim 1, wherein a heat conducting cavity is formed in a side wall of the melting channel, and a heating and heat insulating device is arranged in the heat conducting cavity.
4. An electrically plasticating two-stage dynamic injection molding system as defined in claim 1 further comprising a first valve disposed within said feed channel.
5. An electrically-powered plasticating two-stage dynamic injection molding system as defined in claim 1 further comprising a second valve disposed in a conduit connecting said injection passage to said melt passage.
6. An electric plasticating two-stage dynamic injection molding system as defined in claim 1 wherein said hopper is disposed above said melt channel, said hopper being removably connected to said melt channel.
7. An electric plasticating two-stage dynamic injection molding system as defined in claim 6 wherein said hopper is threadably connected to said melt conduit.
8. An electric plasticating two-stage dynamic injection molding system as defined in claim 1 wherein said hopper is provided with an agitator.
9. The electric plastifying two-stage dynamic injection molding system of claim 8, wherein the agitator comprises a motor, a roller and an agitating blade, the motor is disposed on the hopper, the roller is disposed in the feeding channel, the motor is in driving connection with the roller, and the agitating blade is fixed on the roller.
10. An electro-dynamic plasticating two-stage injection molding system as defined in claim 1 wherein said melt line is disposed parallel to said injection line.
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