JP2009226823A - Screw for plasticizing apparatus, and molding method using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a screw allowing the effective exhaust of gas and moisture in a heating cylinder without having a vent port, and a plasticizing method using the screw. <P>SOLUTION: The screw is provided with a main flight 6 having an outer peripheral diameter slightly smaller than the inner diameter of an inner hole 10 of the heating cylinder 4 and having a first feed zone FZ1, a first compression zone CZ1 and a first metering zone MZ1 sequentially formed forward from the inlet side of a raw material M so as to be gradually lower in flight height, and a decompression zone DZ formed in front of the first metering zone MZ1 so as to be higher in flight height than the first metering zone MZ1, and further a second feed zone FZ2, a second compression zone CZ2 and a second metering zone MZ2 sequentially formed forward from the decompression zone DZ so as to be gradually lower in flight height; and an auxiliary flight 5 having the same pitch and outer peripheral diameter as the main flight 6 from the middle of the first feed zone FZ1 to the middle of the second feed zone FZ2. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a screw used in a plasticizer for a molding machine.

  The gas and moisture generated during the process of plasticizing and melting the raw material in the heating cylinder of the molding machine to form a molten raw material cause defective phenomena such as silver streaks and haze in the molded product formed from the molten raw material. Therefore, conventionally, various measures have been taken to remove gas and moisture from the inside of the heating cylinder. For example, there is one in which gas and moisture generated from a decompression unit provided between two stages of compression units of a screw are degassed from a vent port provided in a middle portion of a heating cylinder. However, this vent system has a problem that the molten raw material swells from the vent port or deteriorated molten raw material near the vent port is mixed into the heating cylinder. In addition, the amount of raw material supplied to the heating cylinder is limited, gas and moisture are circulated from the gap formed in the screw groove to the rear of the screw, and the gas and moisture are spontaneously released from the raw material inlet of the heating cylinder, or a vacuum pump There is also a suction method. However, this method has a lower degassing effect than the vent method.

  By the way, Patent Document 1 discloses a screw of a double screw not for exhausting gas or moisture but conversely for preventing and diffusing gas. However, Patent Document 1 does not describe a specific and detailed description regarding the double screw of the screw, and its form is unknown.

Patent Document 2 discloses a screw in which a first screw groove and a second screw groove are formed adjacent to each other. However, this screw does not have a decompression zone as in the present invention.
Japanese Examined Patent Publication No. 54-6594 (right column, line 5-7, page 2, Fig. 2 (b)) JP-A-63-242509 (page 2, left lower column, lines 12 to 20, line 1)

  The present invention has been made to solve the above-described problems, and provides a screw that can effectively exhaust gas and moisture in a heating cylinder without a vent port, and a plasticizing method using the screw. The purpose is to provide.

  The present invention relates to a screw that is rotatably inserted into a heating cylinder of a plasticizing apparatus and plasticizes a raw material, in which a first feed zone, a first compression zone, and a first meter are sequentially arranged from the rear, which is the inlet side of the raw material, to the front. The ring zone is formed so that the flight height becomes lower sequentially, and the decompression zone adjacent to the front of the first metering zone is formed so that the flight height is higher than the flight height of the first metering zone. Further, a second feed zone, a second compression zone, and a second metering zone are formed in order from the decompression zone in the forward direction so that the flight height decreases sequentially, and the outer diameter is the inner diameter of the inner hole of the heating cylinder. A slightly smaller main flight is provided and the second fee is entered from the middle of the first feed zone. To an intermediate zone, to screw plasticizing device pitch and the outer diameter identical countershaft flights and that of the main flight is provided.

  According to the screw of the present invention and the plasticizing method using the screw, gas and moisture in the heating cylinder can be effectively exhausted without providing a vent port.

  Embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a longitudinal sectional view showing a state in which a screw for carrying out the present invention is fitted into a heating cylinder.

  The screw 3 is rotatably fitted in an inner hole 10 of a heating cylinder 4 provided in a plasticizing device 15 of a molding machine such as an injection molding machine or an extruder. The heating cylinder 4 is a thick cylinder, and one end on the rear side is fixed to a housing (not shown) of the plasticizing device 15, and the cylinder head 1 is fixed to the other end surface on the front. A nozzle or the like (not shown) is fixed to the cylinder head 1. A raw material inlet 7 opening upward is perforated on the side surface of the rear end of the heating cylinder 4. A raw material supply device 13 is airtightly connected to the raw material inlet 7. The raw material supply device 13 is configured to feed a predetermined amount of the raw material M supplied in a two-stage manner while maintaining hermeticity by shutters 11, 11 that are alternately opened and closed, a rotary valve having a recess (not shown), or the like. 12, the conveyance amount is limited and controlled and supplied to the raw material inlet 7. A portion of the screw 3 that is inserted into the inner hole 10 of the heating cylinder 4 and that corresponds to the end of the raw material inlet 7 is a screw base 8. The screw base 8 has a cylindrical shape having a diameter slightly smaller than the inner diameter of the inner hole 10, and is in sliding contact with a packing (not shown) provided on the rear end face of the heating cylinder 4 so that the rear end of the heating cylinder 4 is airtight. . Further, since the groove between the flight pitches is filled with the molten raw material Mm in which the raw material M is melted in front of the screw 3, the inside of the rear portion of the heating cylinder 4 is airtight. Therefore, the vacuum pump 14 provided in the raw material supply device 13 above the raw material inlet 7 can effectively suck the gas and moisture generated from the molten raw material Mm by reducing the pressure inside the heating cylinder 4. In the extruder, the backflow prevention valve 2 is not provided.

  The screw 3 has a main flight 6 and a sub flight 5 at the same pitch on the outer periphery of a round bar whose diameter changes according to the position in the axial direction from the screw base 8 at the rear part to the front end face to which the check valve 2 is fixed. It is formed so as to project spirally and be wound, so that all flights have the same outer diameter and are slightly smaller than the inner diameter of the inner hole 10. And based on the change according to the axial direction position of the diameter of the said round bar, the main flight 6 is the 1st feed zone FZ1, 1st compression zone CZ1, 1st in order from the back which is the inlet_port | entrance side of a raw material to the front. The metering zones MZ1 are formed so that their flight heights are sequentially reduced, and the decompression zone DZ is adjacent to the front of the first metering zone MZ1 and the flight height is the flight height of the first metering zone MZ1. In addition, the second feed zone FZ2, the second compression zone CZ2, and the second metering zone MZ2 are formed so that their flight heights are sequentially reduced from the decompression zone DZ to the front. To do. And the subflight 5 having the same pitch as that of the main flight 6 is provided from the middle of the first feed zone FZ1 to the middle of the second feed zone FZ2.

  Next, plasticization by the screw 3 will be described. The raw material M supplied from the raw material supply device 13 to the inner hole 10 of the heating cylinder 4 via the raw material inlet 7 is a first feed zone FZ1 having a relatively high flight height and a relatively large and constant pitch groove volume. It is conveyed forward while receiving heat from the heating cylinder 4 and the screw 3. The sub flight 5 is formed forward between the intermediate position of the first feed zone FZ1 and the pitch of the main flight 6, and the raw material M starts to melt from the vicinity of this position. The molten raw material Mm in which the raw material M has been melted is unevenly distributed together with the unmelted raw material M on the front side surface of the main flight 6 (the rear side surface when viewed from the pitch groove of the main flight 6). By the way, in the pitch P1 of the main flight 6 where the subflight 5 is provided, the width P2 of the groove 9 on the front side of the pitch P1 of the main flight 6 and the subflight 5 is equal to the pitch P1 distance of the main flight. It is set to 10 to 50%. Therefore, when the supply amount of the raw material M from the raw material supply device 13 is limited, the raw material M and the molten raw material Mm hardly enter the groove 9. That is, in the groove 9, when plasticizing in normal molding, the raw material M and the molten raw material Mm hardly exist, and gas and moisture can be easily circulated. Thus, since the groove 9 is a gas or moisture passage, the narrower the width P2, the larger the width on the rear side of the pitch P1 of the main flight 6 and the sub flight 5, and the plasticity of the raw material M. It is preferable at the point which can prevent the deterioration of crystallization ability. However, when cleaning the screw 3 in order to change the type and color of the raw material M, the raw material M is supplied by the raw material supply device 13 so that the raw material inlet 7 is filled without limiting the supply amount, and the groove 9 In addition, it is necessary that the raw material M and the molten raw material Mm exist and be conveyed. Therefore, the width P2 of the groove 9 is set to 10 to 50% of the pitch P1 distance of the main flight as described above because a certain distance is necessary in consideration of the cleaning effect.

  The first compression zone CZ1 adjacent to the front side of the first feed zone FZ1 is formed so that the flight height is tapered forward from that of the first feed zone FZ1. In the first compression zone CZ1, the raw material M and the molten raw material Mm are compressed and the melting is promoted because the pitch groove volume decreases. The raw material M and the molten raw material Mm increase in the ratio of the molten raw material Mm, and are conveyed while adhering to the entire side surface on the front side of the main flight 6 and being kneaded. Further, the gas and moisture released in this process flow through the gap communicating with the flight grooves of the first compression zone CZ1 and the first feed zone FZ1, and are discharged backward. The first metering zone MZ1 adjacent to the front side of the first compression zone CZ1 is formed so that the flight height is constant from the front end of the first compression zone CZ1 to the front. In the first metering zone MZ1, the raw material M is all melted to become only the molten raw material Mm.

  The decompression zone DZ adjacent to the front side of the first metering zone MZ1 is formed such that the flight height increases in a tapered manner at a short distance of about one pitch from the first metering zone MZ1 to the front. Yes. In the decompression zone DZ, the volume of the pitch groove is rapidly expanded, so that the compressed molten raw material Mm is decompressed, and the gas and moisture contained in the molten raw material Mm are effectively released. The second feed zone FZ2 adjacent to the front of the decompression zone DZ has a constant flight height from the foremost end of the decompression zone DZ to the front. The subflight 5 formed from the middle of the first feed zone FZ1 continues to the middle of the second feed zone FZ2 (more preferably near the rear one pitch position of the second feed zone FZ2). The reason why the secondary flight 5 is not terminated at the foremost end of the decompression DZ but is extended to the middle of the second feed zone FZ2 is that the molten raw material Mm expanded by the rapid decompression in the decompression zone DZ enters the groove 9. This is to prevent backflow and intrusion. The gas and moisture released in the decompression zone DZ easily flow through the spiral groove 9 in which almost no raw material M or molten raw material Mm exists and flow to the rear part of the screw 3. The gas and moisture that have reached the vicinity of the raw material inlet 7 at the rear part of the screw 3 are discharged into the atmosphere through a gap provided as appropriate, or are forced into the air from the space near the raw material inlet 7 that is formed airtight by the vacuum pump 14. Exhausted.

  The second compression zone CZ2 adjacent to the front side of the second feed zone FZ2 is formed so that the flight height is tapered forward from that of the second feed zone FZ2. In the second compression zone CZ2, the molten raw material Mm is compressed because the pitch groove volume decreases, and the melting is promoted / executed again. The second metering zone MZ2 adjacent to the front side of the second compression zone CZ2 has a flight height that is constant from the front end of the second compression zone CZ2 to the front. The second metering zone MZ <b> 2 extrudes a high-quality molten raw material Mm that does not include gas and moisture to the front of the screw 3. In the injection molding machine, a predetermined amount of molten raw material Mm is stored in the front part of the heating cylinder 4, and the screw 3 retracted against the screw back pressure is injected and advanced to inject and fill a mold (not shown).

  Table 1 shows the moisture content of the molded product thus injection-molded together with the moisture content of the molded product molded by an injection molding machine equipped with a conventional screw for comparison. The molding raw material in this molding is an ABS resin material (Clarastic GA-501), and the initial moisture content is about 3000 ppm. The molded product was 200 × 250 mmMax, and the sprue portion was subjected to moisture content measurement. L / D in a table | surface remove | divides the length of a screw by the diameter, and is an parameter | index which shows the effective length of a screw. The L / D20 screw is a general-purpose general-purpose screw. The conventional screw of L / D28 is a screw having only a feed zone, a compression zone, and a metering zone. The screw according to the present invention has a feed zone, a compression zone, and a metering zone in two stages, and has a decompression zone and a subflight, which inevitably resulted in a large L / D.

  As is clear from Table 1, the higher the raw material supply limit and the lower the screw back pressure, the lower the density of the raw material and molten raw material in the pitch groove of the screw and the larger the voids, so moisture discharge Is promoted. Further, when the inside of the heating cylinder is depressurized by vacuum suction, an extremely remarkable decrease in moisture content is observed. In particular, vacuum suction is effective when L / D is increased. This is considered to be due to an increase in the residence time of the molten raw material in the heating cylinder. As described above, the molding using the screw 3 according to the present invention satisfies all the requirements considered to be effective for the discharge of moisture and gas. That is, after the raw material M is completely melted by shearing, the pressure is reduced, the material M is retained for a relatively long time, and the discharged gas and moisture are forcibly sucked and discharged from the secured channel.

  The present invention is not limited to the embodiments described above, and various modifications can be added and implemented without departing from the spirit of the invention.

It is a longitudinal cross-sectional view which shows the state by which the screw which implements this invention was inserted by the heating cylinder.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cylinder head 2 Backflow prevention valve 3 Screw 4 Heating cylinder 5 Sub flight 6 Main flight 7 Raw material inlet 8 Screw base 9 Groove 10 Inner hole 11 Shutter 12 Feed screw 13 Raw material supply apparatus 14 Vacuum pump 15 Plasticizing apparatus M Raw material Mm Melting raw material FZ1 1st feed zone FZ2 2nd feed zone CZ1 1st compression zone CZ2 2nd compression zone MZ1 1st metering zone MZ2 2nd metering zone DZ Decompression zone P1 Main flight pitch P2 Main flight and secondary flight main Groove width on the front side of flight pitch P1

Claims (5)

In the screw that is rotatably inserted into the heating cylinder of the plasticizing device and plasticizes the raw material,
A first feed zone, a first compression zone, and a first metering zone are formed in order from the rear, which is the inlet side of the raw material, in order so that the flight height gradually decreases, and adjacent to the front of the first metering zone The decompression zone to be formed is formed so that the flight height is higher than the flight height of the first metering zone, and further, the second feed zone, the second compression zone, and the second meter are sequentially forward from the decompression zone. A ring zone is formed so that the flight height is sequentially reduced, and a main flight having an outer peripheral diameter slightly smaller than an inner diameter of the inner hole of the heating cylinder is provided, and the middle of the second feed zone from the middle of the first feed zone Up to a subflight with the same pitch and outer diameter as those of the main flight. Screw of the plasticizing device, wherein Rukoto.   The screw of the plasticizing device according to claim 1, wherein a distance between the main flight and the sub flight on the front side of the main flight pitch is 10 to 50% of the main flight pitch distance. A method for molding a plasticizing apparatus using the screw according to claim 1,
A molding method for a plasticizing device, wherein a supply amount of a raw material is limited to such an extent that gas and moisture can flow through a groove formed on the front side of the main flight pitch by the main flight and the sub flight. A method for molding a plasticizing apparatus using the screw according to claim 1,
A method of forming a plasticizing apparatus that does not limit the amount of raw material supplied when the screw is washed. A method for molding a plasticizing apparatus using the screw according to claim 1,
A method for forming a plasticizing apparatus in which the inside of the heating cylinder is in a reduced pressure atmosphere.

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