JP2007076071A - Blow molding machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily carry out position adjustment to make a driving nozzle accord with the central position of the mouthpiece of a mold in a short time. <P>SOLUTION: In a blow molding machine, the driving nozzle 8 is always arranged on the extended line LE of the parting line L of the mold 2, the mold is made movable in the extension direction of the parting line L by a mold moving device 5, and the position adjustment in the parting line direction of the driving nozzle 8 is carried out by moving the mold 2. The position adjustment to make the driving nozzle accord with the central position of the mouthpiece of the mold can be carried out easily in a short time only by finely adjusting the movement of the mold 2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a hollow molding apparatus that can easily adjust the position of a driving nozzle.

  The hollow molding equipment basically consists of an extruder that heats and melts a thermoplastic resin and continuously extrudes it from a die using a screw, and a closed molding in which compressed air is blown into the extruded parison through a driving nozzle. A driving device for expanding in a mold and a take-out device for blown hollow molded products are provided.

  As a conventional device for driving a hollow molding device, there is a device shown in FIGS. 5 and 6 (see, for example, Patent Document 1).

  In FIG. 5, reference numeral 101 denotes a molding die, and a die 102 is provided on the die 101. When a parison (not shown) is inserted into the cavity 101a of the mold 101, the parison is held between a pair of split molds forming the mold 101, and the driving nozzle 103 is driven into the held parison. Rarely, compressed air is blown into the parison from the driving nozzle 103 and blow-molded into a desired container such as a bottle.

  At this time, if the driving nozzle 103 is not positioned at the center of the parison held by the mold 101, the mouth portion of the container is deformed, resulting in defective containers. Therefore, the above-described center alignment work is an important factor in molding a product.

The driving nozzle 103 is attached to the base 107 via the adjustment bracket 104. When the operator turns adjustment screws 105a, 106a, 105b, and 106b provided on the adjustment bracket 104, the driving nozzle 103 is moved. They are moved in the X-axis direction and the Y-axis direction so as to match the center position of the base 102.
JP-A-4-175142

  However, in such a conventional hollow molding machine driving device, it is necessary for the operator to turn the adjusting screws 105a, 106a, 105b, 106b to align the driving nozzle 103 with the center position of the base 102. There is a problem that it takes skill and requires a considerable time for the alignment.

  The present invention is intended to solve the problems of such a conventional hollow molding apparatus, and the position adjustment for aligning the driving nozzle with the center position of the die base of the mold can be performed easily and in a short time. The purpose is to be able to do it.

  In order to achieve the above-mentioned object, the present invention always places a driving nozzle on an extended line of a parting line of a molding die and moves the molding die in a direction in which the parting line extends by a molding die moving device. It is a hollow molding apparatus that can be freely adjusted so that the position of the driving nozzle in the direction of the parting line can be adjusted by moving the molding die.

  The shaft center of the driving nozzle is always located on the line that extends the parting line of the molding die to be used, but this parting line and the extended line change depending on the product to be molded by the molding die to be used. Even if it is, it always exists on the same line.

  The second problem solving means is that the molding die moving device moves the molding die in a direction in which the parting line extends, and a moving rod for reciprocating the molding die on the rail. And an electric motor for driving the movable rod.

  As the moving rod, a ball screw is desirable because it can be finely adjusted. The electric motor is preferable because the servo motor can be finely adjusted, but a linear motor or the like can also be used.

  The third problem solving means is configured such that the moving rod is a ball screw.

  According to a fourth problem solving means, the electric motor is a servo motor.

  The operation of the first problem solving means is as follows. That is, when replacing the molding die corresponding to the product to be molded or the implantation nozzle matched to the mouth of the product, the implantation nozzle to be replaced is arranged on the parting line of the molding die, and the above-mentioned implantation nozzle By adjusting the position in the direction of the parting line only by moving the molding die, it is possible to easily adjust the centering position of the driving nozzle in a short time.

  The operation by the second problem solving means is that the moving rod is driven by driving the electric motor, and the molding die is reciprocated on the rail, so that the fine position adjustment in the direction of the parting line can be performed. The centering position of the driving nozzle can be adjusted easily and in a short time.

  The action of the third problem solving means has an effect that the position of the mold can be adjusted more finely by the ball screw.

  The operation of the fourth problem solving means has the effect that the position of the mold can be adjusted more delicately by the servo motor.

  As described above, the hollow molding apparatus of the present invention can easily center the driving nozzle in a short time when the molding die is replaced or when the driving nozzle is replaced.

  As shown in FIGS. 1 and 2, a hollow molding apparatus according to an embodiment of the present invention includes an extruder (not shown) that melts and extrudes a resin composition as an operation unit for molding, a crosshead 1, A parison cutting device (not shown), a molding die 2, a driving device 3, a clamping device 4 and the like are provided.

  The extruder not shown includes a hopper 7 for charging the resin composition, and a screw not shown for transferring, kneading, melting, and discharging the resin composition inside the extruder.

  As shown in FIG. 1, the crosshead 1 is for multiple heads and is connected to the tip of an extruder. The resin composition melted in the extruder is supplied from the extruder to the crosshead 1, and as shown in FIG. 2, a cylindrical parison P indicated by a two-dot chain line in the figure is formed. Yes.

  The parison cutting device (not shown) cuts the upper part of the cylindrical parison P hanging from the cross head 1 and includes a cutter holder having an electric heating cutter.

  As shown in FIG. 2, the molding die 2 includes a pair of split molds 2 a and 2 b, and in these split molds, a cylindrical parison P is inserted to form a hollow molded product B. A cavity is formed. The molding die 2 is alternately reciprocated in the horizontal direction by the molding die moving device 5 between a position directly below the multi-head crossheads 1 and 1 and a position directly below the driving nozzles 8 and 8 of the driving device 3. It can be moved.

  As shown in FIGS. 1 and 2, the driving device 3 includes left and right driving nozzles 8 for inserting compressed air into the cylindrical parison P above the left and right cavities of the molding die 2. , 8 and a driving nozzle drive device 9 for raising and lowering the driving nozzles 8, 8. The driving nozzle driving device 9 includes an electric motor for driving a variable speed type blowing device connected to a control unit (not shown).

  The driving nozzle 8 is supplied with compressed air from an air source (not shown), and blows air into the cylindrical parison P supplied into the left and right cavities 2 c and 2 d of the molding die 2. . The axes of the driving nozzles 8 and 8 are always positioned on a line obtained by extending the parting line L of the molding die 2 to be used. The parting line L and its extended line are mechanically set so that they always exist on the same line even if the molding die to be used is changed depending on the product to be molded.

  As shown in FIGS. 1 and 2, the mold clamping device 4 clamps the split molds 2a and 2b of the molding die 2 and extends in a pair of horizontal directions arranged at predetermined intervals in the horizontal direction. Rails 12, front platen 10 and rear platen 11 provided at predetermined intervals so as to be movable on these rails 12, and these platens 10, 11 are inserted through these platens with respect to parting line L of molding die 2. The left and right reverse lead ball screws 13 are moved synchronously in the approaching / separating direction, the convex locking portions 14 provided on both sides of the platens 10 and 11, and the concave locking portions 15 for gripping the corresponding convex locking portions. And the ball screw 16 coupled to the concave locking portion 15 so that the concave locking portion 15 can be pulled in a state where the convex locking portion 14 is gripped, and the left and right reverse positions on the back side of the rear platen 11. Lead ball screw A platen moving motor 17 which is connected to 3, and a motor (not shown) is a servo motor for driving the ball screw 16 located on the rear side of the rear platen 11. The front platen 10 is detachably attached with the split mold 2a, and the rear platen 11 is detachably attached with the split mold 2b.

  Each of the left and right ball screws 16 is provided with pulleys 18 and 18 via a thrust bearing (not shown), and these pulleys 18 and 18 are connected to an electric motor (not shown) via an endless belt 19 and a speed reducer 20. .

  The molding die moving device 5 includes a pair of rails 30 and 30 extending in the direction for moving the molding die 2 in the extending direction LE of the parting line L, and a first slide base on which the molding die 2 is placed. A ball screw 32 that reciprocates 31 on a pair of rails 30 and 30 and a servo motor 33 that couples one end of the ball screw 32 and rotationally drives the ball screw 32 are provided. The first slide base 31 includes an engagement portion 40 that engages with the pair of rails 30 and 30 and moves on the rails. As shown in FIGS. 2 and 3, the ball screw 32 is disposed between the pair of rails 30, and the other end of the ball screw 32 can be rotated by a support bracket 39 on the slide base 31. It is supported by. The connecting portion 34 is provided on the lower surface of the first slide base 31 and is attached with a nut (not shown) of the ball screw 32 so as to change the motor rotation into a linear motion in the LE direction.

  The pair of rails 30 are fixedly provided on the second slide base 35. The second slide base 35 is also movable in a direction orthogonal to the parting line L via engaging portions 38 and 38 that engage with a pair of rails 37 and 37 provided on the base 36. It has become.

  Next, the operation of the hollow molding apparatus will be described.

  As shown in FIGS. 1 and 2, the blow molding by the blow molding apparatus hangs the resin from the multi-head crosshead 1 to form left and right cylindrical parisons P in the horizontal direction in FIG. Are inserted into the left and right cavities of the molding die 2, and then compressed air is blown into the parison P from the nozzles 8 and 8 corresponding to the parison P, so that the parison P matches the cavity of the molding die 2. Do by bulging until you do. A bottle which is a hollow molded product is formed by this molding.

  After the mold 2 is opened, the hollow molded product is held by a product holder (not shown) while being suspended from the driving nozzle 8. After the gripping, the blowing nozzle 8 rises, and after the mold 2 moves directly below the driving nozzles 8, 8, a product restraining pin (not shown) inserts the tip of the pin into the mouth of the hollow molded product, Air is introduced into the hollow body that forms the tip of the pin and inflated to hold the hollow molded product from the inside. Thereafter, simultaneously with the opening of the mold, the product holder releases the grip of the molded product.

  Then, the product restraining pin moves to the next flash cutting step. There, the flash is cut and removed, and the hollow molded product is transferred out of the molding apparatus.

  The process of exchanging the mold and / or changing the nozzle according to the size of the mouth of the product accompanying the change of the product to be hollow-molded by such a molding apparatus is performed as follows.

  Here, the pitch between the shaft cores of the changed driving nozzles 8 and 8 and the pitch between the centers of the bases 41 and 41 between the left and right cavities of the molding die 2 are always set to the same dimensions in this molding apparatus. Also, the position of the axis of the driving nozzles 8 and 8 for each product is set mechanically so that it is always on a line LE that extends the parting line L of the molding die 2. Suppose that

  First, using the molding die moving device 5, the die 2 is moved toward the driving nozzles 8, 8 along the extension line LE of the parting line. As shown in FIG. 4, when the misalignment S between the center lines L1 and L2 of the cavities 2b1 and 2b2 and the cores L8 and L8 of the driving nozzles 8 and 8 occurs, the servo motor 33 is driven and the ball screw The operator makes a slight adjustment in the left-right direction while watching the monitor screen (not shown) and the like so that the misalignment S is zero. In FIG. 4, reference numeral 40 denotes a base provided in the mold 2.

  For example, if there is a mechanism that generates 16384 pulses by one rotation of the servo motor 33 and moves the mold 40 mm at that time, if S is 0.1 mm, it is only necessary to move the mold 2 by 41 pulses. Centering can be performed.

  As described above, according to the present embodiment, the effect that centering of the driving nozzle can be performed easily and in a short time can be obtained.

Front view of a hollow molding apparatus showing an embodiment of the present invention 1 is an enlarged side view of the hollow molding apparatus shown in FIG. 1 is a front view of the hollow molding apparatus shown in FIG. Operation diagram showing centering position adjustment of driving nozzle Schematic front view showing a conventional hollow molding device driving device Sectional drawing along the AA line of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 2 ... Molding die 3 ... Punching device 5 ... Molding die moving device 8 ... Punching nozzle 30 ... Rail 31 ... First slide base 32 ... Ball screw 33 ... Servo motor

Claims (4)

The driving nozzle is always arranged on an extended line of the parting line of the molding die, the molding die is movable in the extending direction of the parting line by a molding die moving device, and the parting of the driving nozzle is performed. A hollow molding apparatus characterized in that the position adjustment in the line extending direction can be performed by moving the molding die. A rail that moves the molding die in a direction in which the parting line extends; a moving rod that reciprocates the molding die on the rail; and an electric motor that drives the moving rod. The hollow molding apparatus according to claim 1, comprising: The hollow molding apparatus according to claim 1, wherein the moving rod is a ball screw. The hollow molding apparatus according to claim 1, wherein the electric motor is a servo motor.

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