CA2122282C - Method for injection molding polyethylene terephthalate - Google Patents
Method for injection molding polyethylene terephthalateInfo
- Publication number
- CA2122282C CA2122282C CA 2122282 CA2122282A CA2122282C CA 2122282 C CA2122282 C CA 2122282C CA 2122282 CA2122282 CA 2122282 CA 2122282 A CA2122282 A CA 2122282A CA 2122282 C CA2122282 C CA 2122282C
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- polyethylene terephthalate
- screw
- undried
- stage
- injection
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- Processing And Handling Of Plastics And Other Materials For Molding In General (AREA)
- Blow-Moulding Or Thermoforming Of Plastics Or The Like (AREA)
Abstract
A method for injection molding polyethylene terephthalate by employing a vent type injection unit as means for omitting preliminary drying the resin, wherein the unit does not develop a poor screw biting, and even when a molding material is an undried uncrystallized or crystallized PET, can feed a certain amount of the material at all times to injection mold a desired transparent molded form such as a preform, and use the preform to produce a thin-wall container with a low cost.
Description
TITLE OF THE INVENTION
METHOD FOR INJECTION MOLDING POLYETHYLENE TEREPHTHALATE
BACKGROUND OF THE INVENTION
1. Field of the Invention The present invention relates to a method for injection molding an uncrystallized or crystallized polyethylene terephthalate into a desired molded form such as preform, with pre-drying omitted.
METHOD FOR INJECTION MOLDING POLYETHYLENE TEREPHTHALATE
BACKGROUND OF THE INVENTION
1. Field of the Invention The present invention relates to a method for injection molding an uncrystallized or crystallized polyethylene terephthalate into a desired molded form such as preform, with pre-drying omitted.
2. Background Art A pellet of the polyethylene terephthalate (PET) produced by bulk polymerizing of ethylene glycol with terephthalic acid or dimethyl terephthalate is an uncrystallized and transparent material. The PET whose moisture content does not reach an equilibrium has further moisture-absorption characteristics and thus when the PET is molten in a moisture absorbed condition, a hydrolysis develops to cause the PET not to be molded.
An uncrystallized PET pellet, when heated to a temperature above its glass transition point (Tg), becomes softened somewhat to have an adhesive characteristics. The adhesive characteristics causes the PET pellets to be poorly bitten into a screw and thus not to be fed when molding. On the other hand, a crystallized PET pellet, even at a temperature above its Tg, is not softened, thereby keeping hardness and having no adhesive characteristics.
Thus, material manufacturers dry an uncrystallized PET pellet at a temperature of 150 to 160~C to produce a dehumidified and crystallized PET pellet which is sold as a commercially available molding material. This causes an ordinary and commercially available PET to become more expensive than an uncrystallized PET. The uncrystallized PET, which has been sold by some of material manufacturers, has been dried to effect dehumidification and crystallization by molding manufacturers before use. Therefore, the crystallized PET described herein means a dried commercially available product, while the uncrystallized PET means an undried product. In molding a product using the PET as a material, even the crystallized PET has a moisture-absorption characteristics in nature and thus absorbs moisture content to some extent varying with control conditions before it is used as a molding material, thus it is customary to dry preliminarily the PET immediately before molding.
It takes about four hours to accomplish the preliminary drying at a temperature of 150~C. Both the increased usage of material per hour to improve a molding cycle efficiency, and the consideration to the prevention of a shortage of fed material even for a long time operation cause a dryer installed to an injection molding machine to become inevitably large in size and the power consumption required for drying to tend to increase. Problems exist in that it takes a lot of time to make preparations before molding operation, and that a malfunctioned dryer affects seriously molding operation.
Then, injection molding means omitting the preliminary drying can be devised. As such molding means, there has been known a vent type molding machine in which an injection screw in a heating cylinder is divided into a first stage and a second stage, and the moisture content in a molten resin in the first stage is removed to the outside through a vent opening provided between both the stages.
In this well-known vent type molding machine, the screw groove of a feeding zone of the first stage leading from the rear end at which a hopper is located to a metering zone at the front end is formed in a deep groove; pellets of the material resin fed from the hopper in a humid condition is molten due to shearing heat and compression while being sequentially fed by screw rotation; and then the groove leads through the metering zone having a shallow groove to the second stage.
The screw groove in the second stage is formed in a deep groove, so that when the molten resin is transferred to the groove, the pressure of the molten resin is reduced due to the rapid increase in the groove depth of the screw to cause the moisture content in the resin to be vaporized, and the moisture content wrapped in the resin by screw rotation to be separated, which moisture content is then sucked and removed through the vent opening by a vacuum pump. The molten resin whose moisture content has been removed in this manner is fed by screw rotation to a metering zone at the front end of the second stage, and then to a position in front of the screw to store, in a similar manner to an injection molding machine having an ordinary mechanism. The molten resin thus stored is injected and loaded into a cavity by the forward movement of the injection screw after stoppage of screw rotation.
Although, generally the employment of such vent type injection unit may allow even a material having a large moisture absorption to be molded without the preliminary drying, such unit is not applied to all of resins, and with respect to the PET, particularly an uncrystallized one, the pellet is softened and compressed in a feed zone to cause it to be accumulated, whereby the PET in the hopper cannot enter the zone, and the biting by the screw becomes extremely poor such that the material cannot be fed. As a result, it has been quite difficult to perform the injection molding without the necessity of the preliminary drying by employing a conventional vent type injection unit.
SUMMARY OF THE INVENTION
The present invention is devised to solve problems with the above-mentioned conventional PET injection molding, and it is an object of the invention to provide a method for injection molding the PET by which although a vent type injection unit is employed as means for omitting preliminary drying, the unit does not develop a poor screw biting, and even when a molding material is an uncrystallized or crystallized PET, can feed a certain amount of the material at all times to injection mold a desired transparent molded form such as a preform, and use the preform to produce a thin-wall container with a low cost.
The present invention according to the above-mentioned purpose employs a vent type injection unit in which an injection screw comprising a first stage and a second stage is rotatably and movably mounted in a heating cylinder having a vent, and limits the feed rate of the material resin to a feed zone of the first stage of the vent type injection unit in such a manner that the material resin is not accumulated due to compression even if the material resin is softened to an elastomeric state before reaching a compression zone in front of the feed zone. This limitation is effected by making the sectional area of the screw groove in a receiving zone at the feed zone rear end at which the hopper port of the first stage is located smaller than the sectional area of the screw groove in the feed zone, in which ~122Z~2 condition an uncrystallized or crystallized polyethylene terephthalate produced with the preliminary drying omitted is loaded in the hopper as a material resin to plasticate and inject.
Although it is preferable that the sectional area of the screw groove in the above-mentioned receiving zone 11 is set to no larger than 3/4 the sectional area of the screw groove in feed zone, a smaller sectional area thus set causes the feed rate to become lower and the material metering time to become longer than is required, so that it is most preferable that the former accounts for 2/3 to 1/2 the latter. In order to feed ~aster the PET, the screw is formed in a double screw to the halfway position of the compression zone, and then in a single screw from the compression zone to the metering zone so as to set the screw pitch to a large value, thereby making sufficient the stretching of the molten resin to improve the vent effect in a vent opening of the second zone.
In addition, the molding is performed in such a manner that the heating temperature on the second stage side of the heating cylinder is set to a value lower than the heating temperature on the first stage side, thereby preventing acetaldehyde occurrence due to an overheated molten resin.
The removal of the moisture content in the resin 2l22282 from the above-mentioned heating cylinder is performed by being sucked under a reduced pressure by means of a vacuum pump, which removal is not interrupted even when injecting during operation, and when injecting, the reduced pressure is set to a value lower than that when plasticating, thereby preventing a vent up due to the forward movement of the injection screw. An injection molded preform is immediately or later transferred to a blowing mold, where it can be stretch-blow molded into a packaging container such as a thin-wall bottle.
BRIEF DESCRIPTION OF THE DRAWINGS
Drawings show an example of a vent type injection unit capable of performing the injection molding method of the present invention, in which:
Fig. 1 is a schematic longitudinal sectional and side view of the vent type injection unit according to the present invention, and Fig. 2 is an enlarged side view of a screw provided in the vent type injection unit of Fig. 1, in which a front end thereof is omitted.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
In Figs., the numeral 1 indicates an injection screw which is rotatably and movably inserted into a heating cylinder 2. The injection screw 1 has a shape such that two screws having a deep groove section and a shallow groove section are reconnected to each other to form a single screw, and has a screw design such that a screw portion 10 located in the rear portion of the heating cylinder 2 is made a first stage (10), while a screw 20 located in the front portion thereof is made a second stage (20).
The above-mentioned heating cylinder 2 includes a vent opening 3 on the wall portion on which the rear portion of the second stage 20 is located, which opening is enclosed and connected with a vacuum pump (whose view is omitted). On the rear wall portion on which the rear portion of the first stage 10 is located, there is bored a feed port 4, which is mounted with a hopper 5 for a PET pellet (hereinafter simply called a resin). On the outer periphery of the heating cylinder 2 and a nozzle 6, there are provided band heaters, though omitted in Figs., for heating a resin fed by screw rotation from the above-mentioned feed port 4.
Both the above-mentioned vent opening 3 and the feed port 4 have an opening width with substantially the same size as the pitch of the screw they face.
Fig. 2 shows a screw design of the above-mentioned injection screw 1, in which the ratio of the first stage 10 to the second stage 20 in the overall length L is about 6:4, thus the second stage 20 being formed shorter than the first stage 10. The first stage 10 is divided into four zones of a receiving zone 11, a feed zone 12, a compression zone 13 and a metering zone 14 from the rear end, while the second stage 20 is divided into three zones of a feed zone 21, a compression zone 22 and a metering zone 23 from the rear end.
In the first stage 10 and the second stage 20, the screw is formed in a double screw up to the halfway position of the compression zones 13 and 22 except for the metering zones 14 and 23, whereby the feed of the material resin to the compression zones 13 and 22 by screw rotation is performed as fast as possible; while the screw in the metering zones 14 and 23 is formed in a single screw to widen the screw pitch in order to reduce as small as possible an un-uniformity of the molten resin.
In the first stage 10, the screw pitch P1 of the receiving zone 11 is set to a value smaller than the screw pitch P2 of the feed zone 12, while the screw pitch P3 of the metering zone 14 is set to a value twice the above-mentioned screw pitch P2. The screw pitch of the feed zone 21 and the metering zone 23 of the second stage 20 is set in a similar manner to the screw pitch of the first stage 10.
The screw groove depth of the first stage 10 is set at the dimensions calculated from the screw groove depth of the feed zone 12. In order to limit the feed rate in the feed zone 12, the screw groove depth in the above-mentioned 21222$~
receiving zone 11 is set to a shallow depth such that the sectional area of the screw groove in relation to the above-mentioned screw pitch P1 becomes 2/3 the sectional area of the screw groove of the feed zone 12; while the screw groove depth in the metering zone 14 is set to a depth shallower than in the receiving zone 11 in order to stretch the molten resin by screw rotation.
The screw groove depth in the feed zone 21 of the second stage 20 is set to a deepest depth in order to vaporize the moisture content in the molten resin by a rapid pressure reduction; while the screw groove depth in the metering zone 23 is set to a value deeper than in the metering zone 14 of the first zone 10, thereby making easy the feed of the molten resin by screw rotation.
To injection mold a molded article such as a preform using an uncrystallized PET by employing the vent type injection unit having the above-mentioned arrangement, first the temperature of the heating cylinder 2 that the second stage 20 holds is set to 270~C, and the temperature of the heating cylinder 2 that the first stage 10 holds is set to 280~C. The undried and uncrystallized PET as a molded material is loaded in the above-mentioned hopper 5, and then the injection screw 1 is caused to rotate at a high speed (100 rpm). The atmospheric pressure of the opening 3 is reduced to about -730 mm Hg by the vacuum pump.
_ 10 --21222~2 The PET in the hopper 5 is fed by screw rotation into the receiving zone 11. The feed rate of the PET from the receiving zone 11 to the feed zone 12 is limited to a value accounting for 2/3 the sectional area of the screw groove of the feed zone 12 determined by the above-mentioned screw groove sectional area setting, so that the PET in the feed zone 12 is not excessively accumulated, and thus even if the PET iS softened to an elastomeric state, pellets are not massed with each other due to compression and not accumulate before the resin reaches the compression zone 13.
The PET softened in the feed zone 12 is compressed by the tapered surface of the compression zone 13 to cause it to be molten, stretched and temporarily plasticated, so that the PET is ~ed into the second stage 20 whose temperature is set to a value lower than the first stage 10. The screw groove of the feed zone 21 is formed in a deep groove, so that the pressure of the molten resin is reduced to cause the moisture content in the PET to be vaporized, and the moisture content wrapped in the molten PET by screw rotation to be separated, which moisture content is then sucked and removed through the vent opening 3 by the vacuum pump. The molten PET whose moisture content has been removed in this manner is fed by screw rotation to the metering zone 23 of the second stage 20.and further plasticated, and then fed to a position in front of the screw to store, in a similar manner to an injection molding machine having an ordinary mechanism. As the molten PET is fed, the injection screw 1 is moved backwardly and stopped at a desired position to meter an amount required for injection. After metering, the molten resin is injected and loaded into a mold by forwardly moving the injection screw 1. Then the atmospheric pressure of the vent opening 3 is changed to about -650 mm Hg and maintained by the vacuum pump during injection operation. The atmospheric pressure can be easily controlled by taking the outer air into a suction line through valve operation.
The preform thus injection molded was transparent similarly to the case where a preliminary drying is performed before injection molding, and has no cloudiness due to hydrolysis, and also has an acetaldehyde occurrence within an allowable range.
An example of the specifications of the vent type injection unit of the present invention will be shown hereinafter:
Injection screw (double screw) Screw length (L) :1670 mm Screw outside diameter (D) : 64 mm L/D of Screw : 26 First stage (Length) (Screw minor dia.) Screw pitch Screw 998 mm Receiving zone 128 mm 52.0 mm 32.0 mm Feed zone 646 mm 45.0 mm 38.5 mm Compression zone 64 mm Metering zone 160 mm 57.2 mm 77.0 mm Second stage (Length) (Screw minor dia.) Screw pitch Screw 672 mm Feed zone 448 mm 43.2 mm 38.5 mm Compression zone 64 mm Metering zone 160 mm 56.0 mm 77.0 mm Screw revolution speed : 100 rpm Injection stroke : 120 mm When the PET is crystallized one, it is softened in the feed zone 12 more slowly and transferred to the compression zone 13 faster than the uncrystallized PET, thereby tending to be apt to develop an uneven melting.
However, this problem can be solved by setting the compression zone 13 to a length longer somewhat than the above-mentioned numerical value.
The employment of the above-mentioned vent type injection unit allows the injection molded preform to be molded into a thin-wall packaging container such as a bottle by the well-known stretch-blow molding. The well-known 21~2282 stretch-blow molding is broadly classified into a molding method called the so-called two stage type in which the injection molding of the preform and the stretch-blow molding of the preform into a container are performed in separate processes, and a molding method called the so-called one stage type in which the injection molding of the preform through the stretch-blow molding of the preform into a container are continuously performed, in either of both the methods, the PET preform produced by the injection molding with the preliminary drying omitted can be molded into a thin-wall container as with the PET preform injection molded after being dried.
The following shows molding conditions in a case where with an injection molded preform held at its neck to a limit in which its shape can be kept, the preform is released from a cavity and a core, transferred to a blowing mold when the surface temperature of the preform is being raised due to an internal potential heat, and immediately stretch-blow molded to mold a thin-wall container:
Material resin : UNIPET RY523 (manufactured by Unipet Co.,Ltd.) Molded form : flat bottle Dimensions : overall height 250 mm port inside dia. 23.5 mm length under neck 230 mm body outside dia. 90x50 mm body wall thickness 0.4 mm weight 36 g Preform Dimensions : Overall height 142 mm port inside dia. 23.5 mm length under neck 230 mm body wall thickness 2.9 mm body upper portion outside dia 28 mm body lower end outside dia. 24 mm draft 2/122 Preform molding conditions Injection cylinder temperature First stage : Front 285~C, middle 285~C, rear 280~C
Second stage: Front 270~C, rear 270~C
Nozzle temperature : 270~C
Injection mold temperature (set value) Cavity mold : 15~C
Core mold : 15~C
Injection pressure (dwell) : 75 kg/cm Loading dwell time : 6.0 sec.
Cooling time : 2.8 sec.
Releasing temp. : 60 to 70~C (preform surface temperature) 21222~2 Stretch-blow molding conditions Mold temperature (set value) : 20~C
Stretch-blowing temperature : 88~C (preform surface temperature) Blowing pressure (stretching) : 20 kg/cm Blowing time : 2.0 sec.
Percent of stretch:
Longitudinal (axial direction) 190 %
Lateral (radial direction) 360 x 200 %
As described above, according to the present invention, the injection molding of an uncrystallized PET and that of a crystallized PET with the preliminary drying omitted can be performed by the employment of the vent type injection unit, thereby allowing a molded article having little hydrolysis to be obtained. A molded article developing little acetaldehyde due to overheating is obtained so that the uncrystallized PET having a lower commercial price can be utilized as a molding material, whereby the material cost is reduced and the running cost required for the preliminary drying can be saved even for the crystallized PET, thereby allowing the price of a packaging container using the PET as a material to be reduced. The present invention has a further advantage in that the injection molding itself requires no complex operation and can be performed by employing conventional molding technologies as they are, thereby having a significantly high utility value in industrial field.
An uncrystallized PET pellet, when heated to a temperature above its glass transition point (Tg), becomes softened somewhat to have an adhesive characteristics. The adhesive characteristics causes the PET pellets to be poorly bitten into a screw and thus not to be fed when molding. On the other hand, a crystallized PET pellet, even at a temperature above its Tg, is not softened, thereby keeping hardness and having no adhesive characteristics.
Thus, material manufacturers dry an uncrystallized PET pellet at a temperature of 150 to 160~C to produce a dehumidified and crystallized PET pellet which is sold as a commercially available molding material. This causes an ordinary and commercially available PET to become more expensive than an uncrystallized PET. The uncrystallized PET, which has been sold by some of material manufacturers, has been dried to effect dehumidification and crystallization by molding manufacturers before use. Therefore, the crystallized PET described herein means a dried commercially available product, while the uncrystallized PET means an undried product. In molding a product using the PET as a material, even the crystallized PET has a moisture-absorption characteristics in nature and thus absorbs moisture content to some extent varying with control conditions before it is used as a molding material, thus it is customary to dry preliminarily the PET immediately before molding.
It takes about four hours to accomplish the preliminary drying at a temperature of 150~C. Both the increased usage of material per hour to improve a molding cycle efficiency, and the consideration to the prevention of a shortage of fed material even for a long time operation cause a dryer installed to an injection molding machine to become inevitably large in size and the power consumption required for drying to tend to increase. Problems exist in that it takes a lot of time to make preparations before molding operation, and that a malfunctioned dryer affects seriously molding operation.
Then, injection molding means omitting the preliminary drying can be devised. As such molding means, there has been known a vent type molding machine in which an injection screw in a heating cylinder is divided into a first stage and a second stage, and the moisture content in a molten resin in the first stage is removed to the outside through a vent opening provided between both the stages.
In this well-known vent type molding machine, the screw groove of a feeding zone of the first stage leading from the rear end at which a hopper is located to a metering zone at the front end is formed in a deep groove; pellets of the material resin fed from the hopper in a humid condition is molten due to shearing heat and compression while being sequentially fed by screw rotation; and then the groove leads through the metering zone having a shallow groove to the second stage.
The screw groove in the second stage is formed in a deep groove, so that when the molten resin is transferred to the groove, the pressure of the molten resin is reduced due to the rapid increase in the groove depth of the screw to cause the moisture content in the resin to be vaporized, and the moisture content wrapped in the resin by screw rotation to be separated, which moisture content is then sucked and removed through the vent opening by a vacuum pump. The molten resin whose moisture content has been removed in this manner is fed by screw rotation to a metering zone at the front end of the second stage, and then to a position in front of the screw to store, in a similar manner to an injection molding machine having an ordinary mechanism. The molten resin thus stored is injected and loaded into a cavity by the forward movement of the injection screw after stoppage of screw rotation.
Although, generally the employment of such vent type injection unit may allow even a material having a large moisture absorption to be molded without the preliminary drying, such unit is not applied to all of resins, and with respect to the PET, particularly an uncrystallized one, the pellet is softened and compressed in a feed zone to cause it to be accumulated, whereby the PET in the hopper cannot enter the zone, and the biting by the screw becomes extremely poor such that the material cannot be fed. As a result, it has been quite difficult to perform the injection molding without the necessity of the preliminary drying by employing a conventional vent type injection unit.
SUMMARY OF THE INVENTION
The present invention is devised to solve problems with the above-mentioned conventional PET injection molding, and it is an object of the invention to provide a method for injection molding the PET by which although a vent type injection unit is employed as means for omitting preliminary drying, the unit does not develop a poor screw biting, and even when a molding material is an uncrystallized or crystallized PET, can feed a certain amount of the material at all times to injection mold a desired transparent molded form such as a preform, and use the preform to produce a thin-wall container with a low cost.
The present invention according to the above-mentioned purpose employs a vent type injection unit in which an injection screw comprising a first stage and a second stage is rotatably and movably mounted in a heating cylinder having a vent, and limits the feed rate of the material resin to a feed zone of the first stage of the vent type injection unit in such a manner that the material resin is not accumulated due to compression even if the material resin is softened to an elastomeric state before reaching a compression zone in front of the feed zone. This limitation is effected by making the sectional area of the screw groove in a receiving zone at the feed zone rear end at which the hopper port of the first stage is located smaller than the sectional area of the screw groove in the feed zone, in which ~122Z~2 condition an uncrystallized or crystallized polyethylene terephthalate produced with the preliminary drying omitted is loaded in the hopper as a material resin to plasticate and inject.
Although it is preferable that the sectional area of the screw groove in the above-mentioned receiving zone 11 is set to no larger than 3/4 the sectional area of the screw groove in feed zone, a smaller sectional area thus set causes the feed rate to become lower and the material metering time to become longer than is required, so that it is most preferable that the former accounts for 2/3 to 1/2 the latter. In order to feed ~aster the PET, the screw is formed in a double screw to the halfway position of the compression zone, and then in a single screw from the compression zone to the metering zone so as to set the screw pitch to a large value, thereby making sufficient the stretching of the molten resin to improve the vent effect in a vent opening of the second zone.
In addition, the molding is performed in such a manner that the heating temperature on the second stage side of the heating cylinder is set to a value lower than the heating temperature on the first stage side, thereby preventing acetaldehyde occurrence due to an overheated molten resin.
The removal of the moisture content in the resin 2l22282 from the above-mentioned heating cylinder is performed by being sucked under a reduced pressure by means of a vacuum pump, which removal is not interrupted even when injecting during operation, and when injecting, the reduced pressure is set to a value lower than that when plasticating, thereby preventing a vent up due to the forward movement of the injection screw. An injection molded preform is immediately or later transferred to a blowing mold, where it can be stretch-blow molded into a packaging container such as a thin-wall bottle.
BRIEF DESCRIPTION OF THE DRAWINGS
Drawings show an example of a vent type injection unit capable of performing the injection molding method of the present invention, in which:
Fig. 1 is a schematic longitudinal sectional and side view of the vent type injection unit according to the present invention, and Fig. 2 is an enlarged side view of a screw provided in the vent type injection unit of Fig. 1, in which a front end thereof is omitted.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
In Figs., the numeral 1 indicates an injection screw which is rotatably and movably inserted into a heating cylinder 2. The injection screw 1 has a shape such that two screws having a deep groove section and a shallow groove section are reconnected to each other to form a single screw, and has a screw design such that a screw portion 10 located in the rear portion of the heating cylinder 2 is made a first stage (10), while a screw 20 located in the front portion thereof is made a second stage (20).
The above-mentioned heating cylinder 2 includes a vent opening 3 on the wall portion on which the rear portion of the second stage 20 is located, which opening is enclosed and connected with a vacuum pump (whose view is omitted). On the rear wall portion on which the rear portion of the first stage 10 is located, there is bored a feed port 4, which is mounted with a hopper 5 for a PET pellet (hereinafter simply called a resin). On the outer periphery of the heating cylinder 2 and a nozzle 6, there are provided band heaters, though omitted in Figs., for heating a resin fed by screw rotation from the above-mentioned feed port 4.
Both the above-mentioned vent opening 3 and the feed port 4 have an opening width with substantially the same size as the pitch of the screw they face.
Fig. 2 shows a screw design of the above-mentioned injection screw 1, in which the ratio of the first stage 10 to the second stage 20 in the overall length L is about 6:4, thus the second stage 20 being formed shorter than the first stage 10. The first stage 10 is divided into four zones of a receiving zone 11, a feed zone 12, a compression zone 13 and a metering zone 14 from the rear end, while the second stage 20 is divided into three zones of a feed zone 21, a compression zone 22 and a metering zone 23 from the rear end.
In the first stage 10 and the second stage 20, the screw is formed in a double screw up to the halfway position of the compression zones 13 and 22 except for the metering zones 14 and 23, whereby the feed of the material resin to the compression zones 13 and 22 by screw rotation is performed as fast as possible; while the screw in the metering zones 14 and 23 is formed in a single screw to widen the screw pitch in order to reduce as small as possible an un-uniformity of the molten resin.
In the first stage 10, the screw pitch P1 of the receiving zone 11 is set to a value smaller than the screw pitch P2 of the feed zone 12, while the screw pitch P3 of the metering zone 14 is set to a value twice the above-mentioned screw pitch P2. The screw pitch of the feed zone 21 and the metering zone 23 of the second stage 20 is set in a similar manner to the screw pitch of the first stage 10.
The screw groove depth of the first stage 10 is set at the dimensions calculated from the screw groove depth of the feed zone 12. In order to limit the feed rate in the feed zone 12, the screw groove depth in the above-mentioned 21222$~
receiving zone 11 is set to a shallow depth such that the sectional area of the screw groove in relation to the above-mentioned screw pitch P1 becomes 2/3 the sectional area of the screw groove of the feed zone 12; while the screw groove depth in the metering zone 14 is set to a depth shallower than in the receiving zone 11 in order to stretch the molten resin by screw rotation.
The screw groove depth in the feed zone 21 of the second stage 20 is set to a deepest depth in order to vaporize the moisture content in the molten resin by a rapid pressure reduction; while the screw groove depth in the metering zone 23 is set to a value deeper than in the metering zone 14 of the first zone 10, thereby making easy the feed of the molten resin by screw rotation.
To injection mold a molded article such as a preform using an uncrystallized PET by employing the vent type injection unit having the above-mentioned arrangement, first the temperature of the heating cylinder 2 that the second stage 20 holds is set to 270~C, and the temperature of the heating cylinder 2 that the first stage 10 holds is set to 280~C. The undried and uncrystallized PET as a molded material is loaded in the above-mentioned hopper 5, and then the injection screw 1 is caused to rotate at a high speed (100 rpm). The atmospheric pressure of the opening 3 is reduced to about -730 mm Hg by the vacuum pump.
_ 10 --21222~2 The PET in the hopper 5 is fed by screw rotation into the receiving zone 11. The feed rate of the PET from the receiving zone 11 to the feed zone 12 is limited to a value accounting for 2/3 the sectional area of the screw groove of the feed zone 12 determined by the above-mentioned screw groove sectional area setting, so that the PET in the feed zone 12 is not excessively accumulated, and thus even if the PET iS softened to an elastomeric state, pellets are not massed with each other due to compression and not accumulate before the resin reaches the compression zone 13.
The PET softened in the feed zone 12 is compressed by the tapered surface of the compression zone 13 to cause it to be molten, stretched and temporarily plasticated, so that the PET is ~ed into the second stage 20 whose temperature is set to a value lower than the first stage 10. The screw groove of the feed zone 21 is formed in a deep groove, so that the pressure of the molten resin is reduced to cause the moisture content in the PET to be vaporized, and the moisture content wrapped in the molten PET by screw rotation to be separated, which moisture content is then sucked and removed through the vent opening 3 by the vacuum pump. The molten PET whose moisture content has been removed in this manner is fed by screw rotation to the metering zone 23 of the second stage 20.and further plasticated, and then fed to a position in front of the screw to store, in a similar manner to an injection molding machine having an ordinary mechanism. As the molten PET is fed, the injection screw 1 is moved backwardly and stopped at a desired position to meter an amount required for injection. After metering, the molten resin is injected and loaded into a mold by forwardly moving the injection screw 1. Then the atmospheric pressure of the vent opening 3 is changed to about -650 mm Hg and maintained by the vacuum pump during injection operation. The atmospheric pressure can be easily controlled by taking the outer air into a suction line through valve operation.
The preform thus injection molded was transparent similarly to the case where a preliminary drying is performed before injection molding, and has no cloudiness due to hydrolysis, and also has an acetaldehyde occurrence within an allowable range.
An example of the specifications of the vent type injection unit of the present invention will be shown hereinafter:
Injection screw (double screw) Screw length (L) :1670 mm Screw outside diameter (D) : 64 mm L/D of Screw : 26 First stage (Length) (Screw minor dia.) Screw pitch Screw 998 mm Receiving zone 128 mm 52.0 mm 32.0 mm Feed zone 646 mm 45.0 mm 38.5 mm Compression zone 64 mm Metering zone 160 mm 57.2 mm 77.0 mm Second stage (Length) (Screw minor dia.) Screw pitch Screw 672 mm Feed zone 448 mm 43.2 mm 38.5 mm Compression zone 64 mm Metering zone 160 mm 56.0 mm 77.0 mm Screw revolution speed : 100 rpm Injection stroke : 120 mm When the PET is crystallized one, it is softened in the feed zone 12 more slowly and transferred to the compression zone 13 faster than the uncrystallized PET, thereby tending to be apt to develop an uneven melting.
However, this problem can be solved by setting the compression zone 13 to a length longer somewhat than the above-mentioned numerical value.
The employment of the above-mentioned vent type injection unit allows the injection molded preform to be molded into a thin-wall packaging container such as a bottle by the well-known stretch-blow molding. The well-known 21~2282 stretch-blow molding is broadly classified into a molding method called the so-called two stage type in which the injection molding of the preform and the stretch-blow molding of the preform into a container are performed in separate processes, and a molding method called the so-called one stage type in which the injection molding of the preform through the stretch-blow molding of the preform into a container are continuously performed, in either of both the methods, the PET preform produced by the injection molding with the preliminary drying omitted can be molded into a thin-wall container as with the PET preform injection molded after being dried.
The following shows molding conditions in a case where with an injection molded preform held at its neck to a limit in which its shape can be kept, the preform is released from a cavity and a core, transferred to a blowing mold when the surface temperature of the preform is being raised due to an internal potential heat, and immediately stretch-blow molded to mold a thin-wall container:
Material resin : UNIPET RY523 (manufactured by Unipet Co.,Ltd.) Molded form : flat bottle Dimensions : overall height 250 mm port inside dia. 23.5 mm length under neck 230 mm body outside dia. 90x50 mm body wall thickness 0.4 mm weight 36 g Preform Dimensions : Overall height 142 mm port inside dia. 23.5 mm length under neck 230 mm body wall thickness 2.9 mm body upper portion outside dia 28 mm body lower end outside dia. 24 mm draft 2/122 Preform molding conditions Injection cylinder temperature First stage : Front 285~C, middle 285~C, rear 280~C
Second stage: Front 270~C, rear 270~C
Nozzle temperature : 270~C
Injection mold temperature (set value) Cavity mold : 15~C
Core mold : 15~C
Injection pressure (dwell) : 75 kg/cm Loading dwell time : 6.0 sec.
Cooling time : 2.8 sec.
Releasing temp. : 60 to 70~C (preform surface temperature) 21222~2 Stretch-blow molding conditions Mold temperature (set value) : 20~C
Stretch-blowing temperature : 88~C (preform surface temperature) Blowing pressure (stretching) : 20 kg/cm Blowing time : 2.0 sec.
Percent of stretch:
Longitudinal (axial direction) 190 %
Lateral (radial direction) 360 x 200 %
As described above, according to the present invention, the injection molding of an uncrystallized PET and that of a crystallized PET with the preliminary drying omitted can be performed by the employment of the vent type injection unit, thereby allowing a molded article having little hydrolysis to be obtained. A molded article developing little acetaldehyde due to overheating is obtained so that the uncrystallized PET having a lower commercial price can be utilized as a molding material, whereby the material cost is reduced and the running cost required for the preliminary drying can be saved even for the crystallized PET, thereby allowing the price of a packaging container using the PET as a material to be reduced. The present invention has a further advantage in that the injection molding itself requires no complex operation and can be performed by employing conventional molding technologies as they are, thereby having a significantly high utility value in industrial field.
Claims (10)
1. A method of injection molding an undried polyethylene terephthalate employing a vent-type injection unit comprising a heating cylinder having an inside wall, a vent, a hopper and an injection screw rotatably and movably mounted in the cylinder, the length of the injection screw being divided into sequential first and second stages, each of the first and second stages being divided in sequence into a feed zone, a compression zone and a metering zone, the first stage also having a receiving zone connected to the feed zone of the first stage and receiving the undried polyethylene terephthalate from the hopper, the vent being located at a position corresponding to the feed zone of the second stage, which method comprises:
providing the undried polyethylene terephthalate in the hopper, causing the screw to rotate to thereby convey any polyethylene terephthalate present in the area between the injection screw and the inside wall of the heating cylinder, receiving the polyethylene terephthalate in the receiving zone of the first stage from the hopper, feeding and plasticizing the polyethylene terephthalate, wherein the feeding rate of the polyethylene terephthalate is limited by an arrangement such that the depth of a screw groove in the receiving zone is shallower than the depth of a screw groove in the feed zone, thus making an area available between two adjacent screw flights for molding the polyethylene terephthalate smaller in the receiving zone than in the feed zone of the first stage, and removing volatile substances from the polyethylene terephthalate through the vent.
providing the undried polyethylene terephthalate in the hopper, causing the screw to rotate to thereby convey any polyethylene terephthalate present in the area between the injection screw and the inside wall of the heating cylinder, receiving the polyethylene terephthalate in the receiving zone of the first stage from the hopper, feeding and plasticizing the polyethylene terephthalate, wherein the feeding rate of the polyethylene terephthalate is limited by an arrangement such that the depth of a screw groove in the receiving zone is shallower than the depth of a screw groove in the feed zone, thus making an area available between two adjacent screw flights for molding the polyethylene terephthalate smaller in the receiving zone than in the feed zone of the first stage, and removing volatile substances from the polyethylene terephthalate through the vent.
2. A method of injection molding an undried polyethylene terephthalate according to claim 1, wherein the area available for the polyethylene terephthalate in the receiving zone is not more than 3/4 of the area available for the polyethylene terephthalate in the feed zone of the first stage, and wherein the injection screw in the receiving zone of the first stage, in each of the feeding zones of the first and second stages and in the first half of each of the compression zones of the first and second stages is formed in a double screw, and the injection screw in an area from the first half of each of the compression zones of the first and second stages to each of the metering zones of the first and second stages is formed in a single screw so as to effectively mix and stretch the plasticized polyethylene terephthalate.
3. A method of injection molding an undried polyethylene terephthalate to claim 1 or 2, wherein a reduced pressure is established at the vent whereby moisture contained in the undried polyethylene terephthalate is removed from the vent-type injection unit and extent of the reduced pressure is varied during the injection molding to a lower value.
4. A method for injection molding an undried polyethylene terephthalate as set forth in claim 3, wherein the heating cylinder is heated such that the temperature in the first stage is greater than the temperature in the second stage.
5. A method for injection molding an undried polyethylene terephthalate as set forth in claim 4, wherein the undried polyethylene terephthalate is undried, crystallized polyethylene terephthalate.
6. A method for injection molding an undried polyethylene terephthalate as set forth in claim 4, wherein the undried polyethylene terephthalate is uncrystallized polyethylene terephthalate.
7. A method for injection molding an undried polyethylene terephthalate as set forth in any one of claims 1 to 6, wherein a preform of a thin-wall packaging container to be molded by stretch-blow molding is injection molded.
8. A method for injection molding an undried polyethylene terephthalate as set forth in claim 1, wherein the heating cylinder is heated such that the temperature in the first stage is greater than the temperature in the second stage.
9. A method for invention molding an undried polyethylene terephthalate as set forth in claim 1, wherein the undried polyethylene terephthalate is undried, crystallized polyethylene terephthalate.
10. A method for injection molding an undried polyethylene terephthalate as set forth in claim 1, wherein the undried polyethylene terephthalate is uncrystallized polyethylene terephthalate.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP5-128436 | 1993-04-30 | ||
| JP12843693A JP3289991B2 (en) | 1993-04-30 | 1993-04-30 | Molding method of preform and hollow molded article using amorphous or recycled polyethylene terephthalate |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CA2122282A1 CA2122282A1 (en) | 1994-10-31 |
| CA2122282C true CA2122282C (en) | 1998-02-24 |
Family
ID=14984699
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA 2122282 Expired - Fee Related CA2122282C (en) | 1993-04-30 | 1994-04-27 | Method for injection molding polyethylene terephthalate |
Country Status (4)
| Country | Link |
|---|---|
| JP (1) | JP3289991B2 (en) |
| BR (1) | BR9401024A (en) |
| CA (1) | CA2122282C (en) |
| ZA (1) | ZA942844B (en) |
Families Citing this family (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP3573380B2 (en) * | 1995-08-14 | 2004-10-06 | 株式会社青木固研究所 | Preform injection molding method and stretch blow molding method for polyester resin |
| JPH0994824A (en) * | 1995-09-29 | 1997-04-08 | Aokiko Kenkyusho:Kk | Injection molding method for polyethylene terephthalate |
| US6187229B1 (en) | 1995-11-10 | 2001-02-13 | Nissei Plastic Industrial Co., Ltd. | Process for injection molding information recording disks |
| ES2293861B1 (en) * | 2007-10-04 | 2009-04-01 | Plasticos Hidrosolubles, S.L. | PROCEDURE FOR INJECTION OF POLYETHENOL PARTS. |
| JP6297403B2 (en) * | 2014-05-09 | 2018-03-20 | 日本合成化学工業株式会社 | Manufacturing method of polyvinyl alcohol resin molding |
-
1993
- 1993-04-30 JP JP12843693A patent/JP3289991B2/en not_active Expired - Fee Related
-
1994
- 1994-04-25 ZA ZA942844A patent/ZA942844B/en unknown
- 1994-04-27 CA CA 2122282 patent/CA2122282C/en not_active Expired - Fee Related
- 1994-04-29 BR BR9401024A patent/BR9401024A/en not_active IP Right Cessation
Also Published As
| Publication number | Publication date |
|---|---|
| BR9401024A (en) | 1995-03-28 |
| ZA942844B (en) | 1995-07-04 |
| JPH06315959A (en) | 1994-11-15 |
| JP3289991B2 (en) | 2002-06-10 |
| CA2122282A1 (en) | 1994-10-31 |
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| EEER | Examination request | ||
| MKLA | Lapsed |