Patent Application
20190091901
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The present invention relates to the technical field of injection molding, and more particularly to equipment and a method for supercritical fluid microcellular injection molding.
The conventional foam plastic is mostly made by using physical or chemical additives, wherein gases is released and crafters are formed in the foam plastic during a heating process. As the gasification process is drastic and the temperature distribution in the end product is not uniform such that the crafters are relatively large. In recent years, a new method is provided to replace the conventional foaming agent by supercritical fluid (SCF). The bubble particles are minute, the distribution density is very high and uniform, and the original physical properties of plastics will not be degraded because the phase separation is formed spontaneously and rapidly by the thermodynamic instability resulted from the depressurization cycle.
This technology can improve the conventional plastic foaming method, but it is inapplicable to producing high density styrofoam plates because the surface of the polystyrene plates produced by using the existing supercritical fluid microcellular injection molding method is likely to contract to form wrinkles. The formed wrinkles are very likely to form wavy lines on the surface and influencing the quality of the product after flattening procedure.
The present invention has arisen to mitigate and/or obviate the disadvantages of the conventional injection molding method and products thereof.
The main objective of the present invention is to provide an improved method and equipment for supercritical fluid microcellular injection molding.
To achieve the objective, the supercritical fluid microcellular injection molding method in accordance with the present invention comprises the following steps. Preheating feed pipe: a feed pipe is preheated to a hot melt temperature of polymer. Feeding: polymer is poured into the hopper and enters the feed pipe. An actuating unit is mounted on the feed pipe drives a metering screw rotatably received in the feed pipe. The metering screw is rotated against the feed pipe for forwardly pushing the hot molten polymer to the front end of the feed pipe. Injecting SCF: the SCF is injected into the feed pipe. The metering screw is rotated and mixes the SCF with the hot molten polymer into a homogeneous monophasic fluid. Quantitative discharge and depressurization: the homogeneous monophasic fluid mixed of the SCF and the hot molten polymer flows along the discharge runner through a first gear pump and a second gear pump that are sequentially mounted to a front end of the feed pipe. The first gear pump is provided to maintain the discharge rate per unit time of the discharge runner and the second gear pump reduces a pressure of the monophasic fluid before the monophasic fluid molding because the second gear pump has a feed rate higher than a discharge rate of the first gear pump. Discharging and molding: the monophasic fluid, after being actuated by the first gear pump and the second gear pump, is discharged and molded by the die head mounted on a discharge end of the second gear pump. The gas, in the monophasic fluid, is diffused and nucleated in the molten plastic and grows into uniform microbubbles, after leaving the dishead due to an instant pressure drop state in the discharging process resulting in thermodynamic unbalance, and the plastic with microbubbles is cooled and solidified to obtain the end product of microcellular foam.
Further benefits and advantages of the present invention will become apparent after a careful reading of the detailed description with appropriate reference to the accompanying drawings.
A first gear pump 51 and a second gear pump 52 are sequentially mounted to the front end of the feed pipe 20. The first gear pump 51 has a rotary speed lower than that of the second gear pump 52, and the first gear pump 51 and the second gear pump 52 are provided with a feed end and a discharge end respectively. The feed end of the first gear pump 51 and the discharge runner 21 are interconnected and the discharge end of the first gear pump 51 is connected to the feed end of the second gear pump 52. A die head 521 is mounted onto the discharge end of the second gear pump 52 for injection molding. In addition, the equipment in accordance with the present invention further includes a leveling device 60 coupled with the die head 521. The leveling device 60 comprises multiple rotating rollers 61 situated on a same plan and synchronously operated. In the preferred embodiment of the present invention, the feed rate of the second gear pump 52 is higher than the discharge rate of the first gear pump 51. There are two technical means to implement this effect. Firstly, the feed-discharge ratio of the first gear pump 51 is equivalent to that of the second gear pump 52 and the rotary speed of the second gear pump 52 is higher than the rotary speed of the first gear pump 51. Secondly, the first gear pump 51 and second gear pump 52 have the same rotary speed, and the feed-discharge ratio of the second gear pump 52 is higher than the feed-discharge ratio of the first gear pump 51.
Referring to
Preheating a feed pipe 20: the feed pipe 20 is preheated to a hot melt temperature of the polymer to be used, as to produce high density styrofoam plates, the polystyrene (PS) at melting point about 240° C. is used such that the preheating temperature of the feed pipe 20 is set about 240° C. In addition, the glass transition temperature of the polystyrene is higher than 100° C., so that the styrofoam plates produced by the method in accordance with the present invention are capable of making various wash-free containers (tableware and the like) that resistant to a high temperature.
Feeding: the polymer is poured into the hopper 22 and enters the feed pipe 20. Meanwhile the actuating unit 10 drives the metering screw 30 and the metering screw 30 rotates against the feed pipe 20 for forwardly pushing the hot molten polymer to the front end of the feed pipe 20.
Injecting SCF: the injection valve 23 is turn on to inject the SCF (N2 or CO2), supplied from the high pressure gas source 40, into feed pipe 20. The metering screw 30 is rotated and mixes the SCF with the hot molten polymer into a homogeneous monophasic fluid. The supply pressure is about 12 Mpa when the SCF, supplied from the high pressure gas source 40, is N2 and the supply pressure is 5-6 Mpa when the SCF, supplied from the high pressure gas source 40, is CO2. A pressure reducing valve 41 is disposed between the injection valve 23 and the high pressure gas source 40 such that the high pressure liquid gas, supplied from the high pressure gas source 40, is depressurized into a gas-liquid coexistent supercritical state under the regulating effect of the pressure reducing valve 41, which is injected through the injection valve 23 into the feed pipe 20, wherein the output pressure value of exit end is kept automatically by the structure property of pressure reducing valve 41.
Maintaining constant pressure: the feed pipe 20 is provided with at least one pressure sensor 25 and the back pressure regulator 242, connected via exhaust line 241 to the exhaust structure 24, is electrically connected to the at least one pressure sensor 25. The back pressure regulator 242 opens the exhaust line 241 to relieve the pressure in the feed pipe 20 when the pressure in the feed pipe 20, detected by the at least one pressure sensor 25, is higher than the maximum value of the preset operating pressure. The back pressure regulator 242 closes the exhaust line 241 to keep the operating pressure in the feed pipe 20 in the tolerant pressure range when the pressure in the feed pipe 20 detected by the at least one pressure sensor 25 is lower than the minimum value of the preset operating pressure.
Quantitative discharge and depressurization: the homogeneous monophasic fluid mixed of the SCF and the hot molten polymer flows along the discharge runner 21 through the first gear pump 51 and the second gear pump 52. The major function of the first gear pump 51 is to maintain the discharge rate per unit time of the discharge runner 21 and the second gear pump 52 reduces the pressure of the monophasic fluid before the monophasic fluid molding because the second gear pump 52 has a rotary speed higher than that of the first gear pump 51.
Discharging and molding: the monophasic fluid, after being actuated by the first gear pump 51 and the second gear pump 52, is discharged and molded by the die head 521. The gas, in the monophasic fluid, is diffused and nucleated in the molten plastic, and grows into uniform microbubbles after leaving the die head 521 due to an instant pressure drop state in the discharge process resulting in thermodynamic unbalance. Furthermore, the plastic with microbubbles is cooled and solidified to obtain the end product of microcellular foam (styrofoam plate).
Leveling: the cooled plate, injected from the die head 521, crosses the multiple rotating rollers 61 in waves for leveling operation, and eliminating a stress of the plate after molding and the warpage resulted from the stress.
The method in accordance with the present invention uses the depressurization resulted from the speed difference between the first gear pump 51 and the second gear pump 52 to eliminate the contraction induced wrinkles on the surface of styrofoam plates produced through conventional process, so that the subsequent molded products are free of unwanted lines, the added value of polystyrene plates is increased, and the marketability of subsequent molded products is enhanced.
Although the invention has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the invention as hereinafter claimed.
