KR101126570B1 - apparatus for forming film by blowing thermoplastic resin - Google Patents

Abstract

The present invention is provided between the stabilization means and the cooling air ring to provide a frame mounted with a tubular portion capable of enclosing a tube, the air frame by allowing the frame to move up and down between the stabilizer and the cooling air ring, It is possible to selectively position the tubular portion in the different air blowing weak spots according to the diameter of the tube to reach the stabilization means to reduce the manufacturing cost and maintenance cost of the tubular portion that is the windbreak barrier, Even when an abnormality occurs in the stabilization means and the air ring, it is possible for the operator to quickly approach the stabilization means and the air ring.

Description

Apparatus for forming film by blowing thermoplastic resin

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for inflating a thermoplastic resin into a film, and more particularly, to an air barrier wall provided in the film forming apparatus.

As shown in FIG. 6, the conventional film forming apparatus includes a compressor 11, an annular die 12 mounted on the compressor 11, and a cooling air ring 13 provided on the annular die 12. ), A stabilizing means (15) for folding the tube, a pair of pinch rolls (16), and a winding roller (18) of the film (17). In the center of the annular die 12, a pipe 19 connected to a supply device (not shown) of air 24 is provided.

In the stabilization means 15, a plurality of rollers 21 are arranged in parallel in parallel along the longitudinal direction, and the plurality of rollers 21 are arranged on one side and the other side with the tube 14 interposed therebetween. It is. A heat insulating wall 22 made of a heat insulating material is provided around the stabilization means 15 except for the passage portion of the film 17. In addition, a hot wind supply means (not shown) for supplying hot air is provided inside the heat insulation wall 22.

A guide roller 23 is provided between the pinch roller 16 and the take-up roller 18.

The film forming apparatus configured as described above is operated as follows.

The raw material resin is introduced into the extruder 11 to be melt kneaded, and the molten resin is extruded into a cylindrical shape from the annular die 12 to be shaped into a tube 14 shape. The tube 14 is cooled from the cooling air ring 13 to the air 24 while inflating the air 24 into the tube 14 to expand to a desired diameter.

Then, the tube 14 is introduced into the stabilizing means 15 having the plurality of rollers 21 to make a flat film 17, and continuously pulled to wind the film 17 on the winding roller 18. do.

In this conventional film forming apparatus, the air ring 13 and the stabilization means 15 are disposed at a considerable distance compared to the diameter of the tube for curing the tube 14. Due to this arrangement, the tube 14 exiting the air ring 13 and reaching the stabilization means 15 is sensitive to drafts at local locations in the vertical direction, depending on the diameter of the tube being made.

In order to solve this problem, a tubular portion concentric with the center of the tube 14 is disposed radially outwardly on all parts of the tube 14 disposed between the air ring and the stabilization means by a soft cloth. Although all the parts of the tube 14 disposed between the air ring and the stabilization means are disposed in the tubular portion, the manufacturing cost and the maintenance cost are increased, and abnormality is caused in the stabilization means and the air ring. When it occurs, the conventional film forming apparatus has a problem that it is difficult for the worker to quickly access the stabilizing means and the air ring.

The present invention has a problem in solving the above problems.

The present invention is provided between the stabilization means and the cooling air ring is provided with a frame mounted with a tubular portion capable of enclosing the tube, the frame is the object by allowing the frame to move up and down between the stabilizer and the cooling air ring Can be solved.

The present invention, by the above-described problem solving means, it is possible to selectively position the tubular portion in the different air blowing weak part according to the diameter of the tube discharged from the air ring to reach the stabilizing means, a tubular windbreak wall It is possible to reduce negative manufacturing cost and maintenance cost, and at the same time, even if an abnormality occurs in the stabilization means and the air ring, the operator can quickly access the stabilization means and air ring.

1 is a conceptual diagram of a film forming apparatus equipped with a draft blocking means of this embodiment;
Figure 2 is a front view of the draft blocking means of Figure 1,
3 is a left side view of the draft blocking means of FIG. 1;
4 is a rear view of the draft blocking means of FIG. 1;
5 is a plan view of the draft blocking means of FIG. 1, and
6 is a conceptual diagram of a conventional film forming apparatus.

Hereinafter, an embodiment according to the present invention will be described with reference to FIGS. 1 to 5.

In Fig. 1, the film forming apparatus according to the present embodiment is indicated by the reference numeral 100.

The film forming apparatus, like a conventional film forming apparatus, has a compressor 11, an annular die 12 attached to the compressor 11, and a cooling air ring 13 provided on the annular die 12. And a stabilizing means (15) for folding the tube, a pair of pinch rollers (16), and a winding roller (not shown) of the film (17).

In addition to the above-described configuration, the film forming apparatus 100 includes an air blowing block 400 between the stabilization means 15 and the cooling air ring 13.

As shown in FIGS. 2 to 5, the draft blocking means 400 is disposed in the hexahedral frame frame 410 fixedly disposed below the stabilization means 15, and the hexahedral frame frame 410. The moving body 420 is included.

The movable body 420 has a top plate 421 having a through hole 422 having a size through which the tube 14 can pass, and is spaced at a predetermined interval in a vertical direction with respect to the top plate 421 and the top plate 421. A lower plate 424 having the same center as the center of the through hole 422, and having a through hole 423 having the same size and shape as the through hole 422, and the upper plate 421 and the lower plate 424 from each other. In order to be coupled to the upper plate 421 and the lower plate 424 includes four standing rods 425 are coupled to the top and bottom of the four corners.

As shown in FIGS. 2 and 3, the hexahedral frame frame 410 is a male screw erectably rotatable upper and lower portions at the center of the upper frame 411a and the lower frame 411b of the front rectangular frame 411. A shaft 414a is provided, and as shown in FIGS. 3 and 4, the upper and lower parts are rotatably mounted at the center of the upper frame 413a and the lower frame 413b of the rear rectangular frame 413. The male screw standing shaft 414b is provided.

In addition, as shown in FIGS. 2 and 4, the front rectangular frame 411 and the rear rectangular frame 413 are spaced apart from each other in the horizontal direction at regular intervals with respect to the male screw standing shafts 414a and 414b. Guide rising bars 416a and 416b parallel to the male screw standing shafts 414a and 414b are provided.

The hexahedron frame 410 and the movable body 420 are coupled to each other via a pair of brackets 430a and 430b so that the movable body 420 can be protruded from the hexahedral frame frame 410.

One side of the pair of brackets 430a and 430b is fixed to the front and rear sides of the bottom surface of the upper plate 421 of the movable body 420 by fastening means. On the other side of the pair of brackets 430a and 430b, the through holes 432a and 432b in which the nuts 431a and 431b are fixed and inscribed, and the through holes 434a and 434b in which the bushes 433a and 433b are fixed and inscribed, are provided. The male screw standing shafts 414a and 414b are penetrated and fastened to the nuts 431a and 431b, respectively, and the guide standing bars 416a and 416b are slidable to the bushes 433a and 433b, respectively. Penetrated

Helical gears 441a and 441b are fixedly circumscribed on the upper ends of the male screw standing shafts 414a and 414b exposed through the upper sides 411a and 413a of the front and rear rectangular frames 411 and 413, and the upper sides On the upper surfaces of the molds 411a and 413a, the helical gears 442a and 442b, one end of which is engaged with the helical gears 441a and 441b, are fixedly circumscribed, and the other end is fixedly circumscribed to the sprockets 443a and 443b. Driven shafts 444a and 444b are rotatably mounted via bearings.

A worm wheel 446 is fixedly circumscribed on one of the driven shafts 444a of the driven shafts 444a and 444b, and the worm wheel 446 is coupled to a drive shaft of the reversible motor M. 447) is interlocked.

As shown in FIG. 3, the chain 448 is wound around the sprockets 443a and 433b disposed on the upper sides 411a and 413a of the front and rear rectangular frames 411 and 413. When rotated in the forward direction, the driven shafts 444a and 444b simultaneously rotate in one of the clockwise and counterclockwise directions in the city via the chain 448 and the sprockets 443a and 44b, thereby allowing the male screw standing shaft 414a to be rotated. , 414b are simultaneously rotated simultaneously in either a clockwise or counterclockwise direction, such that the movable body 420 moves in one of the up and down directions from the vertical direction, and the motor M is reversed. When rotated to, the movable body 420 is moved in the other direction.

As illustrated in FIGS. 2 to 5, an outside air blocking unit 500 is mounted on an upper surface of the portion 424a of the lower plate 424, which is an edge portion defining the through hole 433.

The draft cutoff portion 500 has an inner diameter larger than the diameter of the through hole 433 and has a flat top and bottom surfaces that are flat on the portion 424a of the lower plate 424. ); As a wind-blocking tubular wall which is in surface contact with the inner circumferential surface of the ring-shaped portion 501 and is placed on the portion 424a of the lower plate 424 and extends vertically from the lower plate 424 to the upper plate 421. The air-blocking tubular wall 502 having an inner diameter larger than the diameter of the through hole 433 and made of acrylic material; And a guide tubular portion having an inner diameter capable of surface contact with the tube 14 penetrating through the through hole 433, and having a height lower than that of the draft blocking tubular wall 502. A flange 503a extending in the direction is formed at the lower end thereof and is placed on the portion 424a of the lower plate 424 in a state where the tip of the flange 503a is inscribed in the airflow blocking tubular wall 502, The inner circumferential surface includes the guide tubular portion 503 made of a metal material coated with a material having heat resistance and sliding property so as to be in sliding contact with the tube 14.

The plurality of brackets 504, one end of which is detachably mounted to the lower plate 424 by fastening means such as a bolt, and the other end of which is in surface contact with the upper surface of the ring-shaped portion 501. It is fixed to the lower plate 424 through).

The plurality of brackets 504 are arranged at regular intervals from each other in the circumferential direction of the ring-shaped portion 501.

The film forming apparatus 100 having the draft blocking means 400 configured as described above is capable of selectively positioning the draft blocking walls at different draft weakening portions according to the diameter of the tube discharged from the air ring to reach the stabilizing means. In this way, it is possible to reduce the manufacturing cost and the maintenance cost of the draft blocking wall, and at the same time, even if an abnormality occurs in the stabilization means and the air ring, the operator can quickly access the stabilization means and the air ring. .

In addition, the draft blocking means 400 configured as described above causes the guide tubular portion 503 to be in surface contact with the tube 14 locally, so that the draft is outside the region of the draft blocking means 400. It can be delivered to (14) to prevent the tube (14) from rocking.

11; Compressor, 12; Die, 13; Cooling air ring, 14; Tube, 15; Stabilizer, 16; A pair of pinch rollers, 17; Film, 18; Winding roller, 19; Pipe, 21; Roller, 22; Insulating wall, 23; Guide roller, 24; Air, 100; Film forming apparatus, 400; Draft blocking means, 410; Hexahedral frame, 411; Anterior rectangular frame, 411a; Upper frame, 411b; Lower frame, 413; Rear rectangular frame, 413a; Upper frame, 413b; Lower frame, 414a; Male screw standing shaft, 414b; Male screw standing shaft, 416a; Guide standing rods, 416b; Guide standing rods, 420; Moving body, 421; Top, 422; Through hole, 423; Through hole, 424; Bottom plate, 425; Standing rods, 430a; Bracket, 430b; Bracket, 431a; Nut, 431b; Nut, 432a; Through-hole, 432b; Through hole, 433a; Bush, 433b; Bush, 434a; Through-hole, 434b; Through hole, 441a; Helical gears, 441b; Helical gears, 442a; Helical gears, 442b; Helical gears, 443a; Sprocket, 443b; Sprocket, 444a; Driven shaft, 444b; Driven shaft, 446; Worm wheel, 447; Warham, 448; Chain, M; Motor, 500; Draft cut-out, 501; Ring-shaped, 502; Draft blocking tubular wall, 503; Guide tubular portion 503a; Flange, 504; Bracket

Claims (3)

Compressor 11, annular die 12 mounted on compressor 11, cooling air ring 13 provided on annular die 12, stabilization means 15 for folding the tube, a pair of A film forming apparatus comprising a pinch roller 16 and a take-up roller 18 of a film 17. A plurality of rollers 21 are arranged in parallel in the longitudinal direction in the stabilization means 15, In the film forming apparatus 100, these rollers 21 are arranged on one side and the other side with the tube 14 interposed therebetween,
It further comprises a draft blocking means 400 between the stabilization means 15 and the cooling air ring 13,
The draft blocking means 400 includes a hexahedral frame frame 410 fixedly disposed below the stabilization means 15 and a movable body 420 disposed in the hexahedral frame frame 410.
The movable body 420 has a top plate 421 having a through hole 422 having a size through which the tube 14 can pass, and is spaced at a predetermined interval in a vertical direction with respect to the top plate 421 and the top plate 421. A lower plate 424 having the same center as the center of the through hole 422, and having a through hole 423 having the same size and shape as the through hole 422, and the upper plate 421 and the lower plate 424 from each other. It includes four standing rods 425, the top and bottom are coupled to the four corners of the upper plate 421 and the lower plate 424 for coupling,
The hexahedral frame frame 410 is provided with a male screw standing shaft 414a rotatably mounted on the upper and lower frames 411a and the lower frame 411b of the front rectangular frame 411, and rearward. In the center of the upper frame 413a and the lower frame 413b of the rectangular frame 413, a male screw standing shaft 414b rotatably mounted at an upper side and a lower side is provided.
Each of the front rectangular frame 411 and the rear rectangular frame 413 is spaced in a horizontal direction at regular intervals with respect to the male screw standing shafts 414a and 414b and is parallel to the male screw standing shafts 414a and 414b. 416a, 416b are provided,
The hexahedral frame 410 and the movable body 420, the male screw standing shafts (414a, 414b) and the guide standing bar 416a, so that the movable body 420 is protruding from the hexahedral frame frame 410 416b) are coupled to each other via a pair of brackets (430a, 430b) through which,
The male screw standing shafts 414a and 414b are simultaneously driven in the same direction by one reversible drive source and mechanical interlocking means,
The outer wind shield 500 is mounted on an upper surface of the portion 424a of the lower plate 424, which is an edge portion for partitioning the through hole 433,
The draft cut-out 500 is in flat contact with the inner circumferential surface of the ring-shaped portion 501 and the ring-shaped portion 501 which is placed on the portion 424a of the lower plate 424, and the portion of the lower plate 424. The wind-blocking tubular wall 502 which is placed on the 424a, and has an inner diameter which can be brought into surface contact with the tube 14 penetrating through the through hole 433 in a sliding manner. A guide tubular portion having a height lower than the height of the bottom plate; a flange 503a extending radially outward is formed at a lower end thereof, and the lower plate And a tubular portion (503) mounted on the portion (424a) of the portion (424). The method of claim 1,
One side of the pair of brackets 430a and 430b is fixed to the front and rear sides of the bottom surface of the top plate 421 of the movable body 420 by fastening means.
On the other side of the pair of brackets 430a and 430b, there are formed through holes 432a and 432b in which nuts 431a and 431b are fixed and inscribed, and through holes 434a and 434b in which bushes 433a and 433b are fixed and inscribed. It is,
The male screw standing shafts 414a and 414b are respectively penetrated and fastened to the nuts 431a and 431b.
The bush (433a, 433b) is a device for forming a film by inflating the thermoplastic resin, characterized in that the guide penetrating rods (416a, 416b) are slidably penetrated, respectively. 3. The method according to claim 1 or 2,
Helical gears 441a and 441b are externally fixed and circumscribed at the upper ends of the male screw standing shafts 414a and 414b exposed through the upper sides 411a and 413a of the front and rear rectangular frames 411 and 413,
On the upper surfaces of the upper frames 411a and 413a, helical gears 442a and 442b, one end of which is engaged with the helical gears 441a and 441b, are fixedly circumscribed, and the other end is fixed to the sprockets 443a and 443b. The driven shafts 444a and 444b circumscribed to each other are rotatably mounted via bearings,
A worm wheel 446 is fixedly circumscribed on one of the driven shafts 444a of the driven shafts 444a and 444b, and the worm wheel 446 is coupled to a drive shaft of the reversible motor M. 447) is interlocked,
The sprocket (443a, 433b) disposed in the upper frame (411a, 413a) of the front and rear rectangular frame (411, 413), the chain 448 is wound, characterized in that the thermoplastic resin inflated to form a film.

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