DE3400653A1 - AIR RING FOR FILM BLOW MOLDING - Google Patents

Description

Air ring for film blow molding

The invention relates to an air ring for blown film molding or blow molding films, and particularly relates to such an air ring comprised of a plurality of branching slots are provided to allow air to flow onto an extruded film inflating more than one direction for better molding results.

The blow molding process is a widespread and well-known one Technique for blowing thin films from thermoplastic synthetic resins and is used in the manufacture of food casings and plastic bags are widely used. While doing this It has been known in the process that there are various problems which could somehow be eliminated. These problems become particularly severe when the molding speed is increased. Some of the while doing blow molding Problems encountered consist of blocking, jamming or clogging, whereby as a result of incorrect cooling of the formed Part of the film sticks to the other, so that difficulties arise in the subsequent process, unequal wall thicknesses of the film, lack of transparency, etc., which significantly affect the commercial value of the end product.

It is in view of these disadvantages and difficulties in the prior art that the main object of the invention is is to provide an air ring which does not have the disadvantages mentioned above, namely greater cooling effect than conventional in blow molding thermoplastic resins such as polyethylene, polyester, polypropylene, polyamide, etc., and in particular the creation of an air ring that creates a well-transparent, tubular film by blow molding low density polyethylene (L-LDPE) or the like can generate.

According to this invention the object is achieved in that

an air ring for film blow molding is provided in which cooling is achieved by letting cooling air out is blown into a horizontal ring slot after the film is extruded from a die, wherein an air ring main body consists of a hollow ring body and the connection with an air supply pipe provides an annular body forming a slot substantially coaxial with and within the air ring main body the same is arranged for the formation of a primary air outlet, with the horizontal annular slot for cooling of the formed film is provided by blowing cooling air. and wherein a channel is provided which the air ring main body connects to the primary air outlet and to another annular body forming an air slot; there is the Channel in the latter, the slot-forming ring body provided branching into a plurality of slots for blowing the cooling air onto the extruded film from more than one direction.

Further advantages, features and possible applications of the present invention emerge from the following description preferred embodiments in conjunction with the drawings. Show it:

Figure 1 is a front view of an embodiment of the air ring according to the invention, which is used in a blow molding process, Figure 2 is a horizontal section along the line II-II of Figure 1,
Figure 3 is a vertical section along the line III-III of Figure 2 on an enlarged scale,

FIG. 4 shows an enlarged view of part of FIG. 3, FIG. 5 shows a partially broken away plan view of the annular cover,

FIG. 6 shows an enlarged view of part of FIG. 5, FIG. 7 shows the plan view of part of the annular valve unit for straightening the air flow, Figure 8 another embodiment of the slot forming

the body and

FIG. 9 is a sectional view similar to that of FIG. 3, showing a device for adapting the Air ring to a smaller die.

The reference number 1 denotes a stamp or embossing or drawing stamp, which is designed so that molten thermoplastic resin can be extruded, which is fed from an extruder 2 connected to the lower part of the punch 1 is connected via an annular lip 1a which is provided on the upper surface of the punch 1 so that a bladder 3 made of a tubular thin film is molded.

The punch 1 is supported on the extruder 2 by means of a rotor 4 which is connected to its lower end, see above that it is rotatable about a vertical, axial line, and it in turn holds an air ring 6 by means of L-shaped support arms 5, extending from the circumference of the upper surface of the punch 1 extend out.

As shown in Fig. 3, an air ring main body 7, which forms a hollow ring passage 7a, consists of three Casings; i.e. a movable or lower housing 8 with an opening upwards, a fixed or side housing 9, which is also ring-shaped and has an opening inwards on its lower part, and an upper housing 10, which covers the inward upper side of the air ring main body 7.

A ball bearing 11 is between the upper end surface of the annular outer wall 8a of the lower housing 8 and a bottom wall 9a of the side housing 9, and the therebetween The gap located is sealed airtight by a sealing ring 12.

An annular wall 10a is provided around the outer periphery of the upper case 10 and is in sliding engagement with a

^: " ^: ■ - ' 3400653 -δι similar ring wall 9a of the side housing 9, the gap between them being sealed airtight by a sealing ring 13.

Between the lower surface of the upper housing 10 and the upper end of the annular inner wall 8b is a Arranged ring opening 14, which is directed inwardly. An annular valve unit 15 for straightening or aligning the air flow (see Fig. 7) with a plurality of vertically extending holes 15a along the circumferential direction is inserted between the ring wall 10a and the ring inner wall 8b.

The upper housing 10 and the lower housing 8 are connected by screws 16 to form an integral body.

The lower surface of the bottom plate 8c of the upper case is attached to support arms 5 with screws 17 at its inner parts appropriate.

A plurality of support arms 20 are on the outer part of the side housing 9, and a horizontal shaft 18 is mounted on the lower part of each of these support arms 20. These horizontal shafts 18 each support a roller 19 in freely rotatable way.

The lower surface of the lower case 8 is freely rotatably supported by these rollers 19.

A chain 21 is along the outer circumference of the ring outer wall 8a of the lower housing 8 attached. By creating this chain 21, it becomes possible to use the lower case 8 alone to rotate if the punch 1. is not to be rotated, by removing the support arms 5 and letting them comb the chain 21 with a sprocket, which is not shown in the drawings.

As shown in Figure 2, a pair of air supply ducts

Openings 22 on the outer circumferential surface of the side housing 9 provided along the tangential directions for the introduction of cooling air into the air ring main body 7.

After this cooling air from the annular valve unit 15 is straightened for aligning the air flow, it passes through the opening 14 and is out of the vertically spaced two slots for the primary and secondary cooling blown out by two Kinds of ring members forming slits are formed, which will be described in more detail below, and to cool the bladder 3.

Reference numerals 23, 24, 25 and 26 in FIG four inverted frustoconical channels forming bodies, which form a first annular body 28 forming a slot for forming the slot 27 for the primary cooling, and by arranging these channels forming bodies just like a group of nested boxes. 20th

Horizontal flanges 23a, 24a, 25a and 26a are on the top opening ends of these channel-forming bodies, extending outward, provided, while horizontal and self inwardly extending flanges 23b, 24b and 25b on the lower opening ends of the three lower channel-forming bodies 23, 24, and 25 are provided.

The inwardly extending flanges 2 3b, 24b and 25b at the lower ends of the channel-forming bodies 23, 24 and 25 are each with a substantially coaxial, continuous Hole 29 is provided, the diameter of which is slightly larger than the lip 1 a of the stamp 1. The bottom end surface 26b of the uppermost channel-forming body 26 forms another through hole 30, the diameter of which is somewhat larger than the aforementioned through hole 2 is 9.

The channel-forming bodies 23, 24, 25 and 26 can be independently moved along the vertical or axial direction thereby

-ΙΟΙ are moved that the threaded insert parts 23c, 24c, 25c and 26c of the outer peripheral surfaces of the flanges 23a, 24a, ■ 25a and 2 6a on the upper parts of the channel-forming bodies 23, 24, 2 5 and 2 6 with a female thread part 8d of the inner peripheral surface the inner ring wall 8b of the lower housing 8 are threaded, and cooling air ducts 31, 32 and 33 are formed between the channel-forming bodies 23, 24, 25 and 2 6 in this order when you start with the Counting starts from the lowest.

The flanges 24a, 25a and 26a of the upper three channel-forming bodies 24, 25 and 26 are each with a plurality of through holes 34, 35 and 36 are provided to allow the cooling air flowing out of the opening 14 through there into the channels 31, 32, 33 and 34 to flow into it, and the * oberoi surfaces of the inner end portion of the flanges 2 4a and 25a are provided with annular projections 24d and 25d for adjusting the side of the channels 32 and 33.

Next, the three branching slots that make up slot 27 for primary cooling will be described represent or form.

The inner end of the central channel 32 is formed into a second branched slot 38 with one upward inclined ring shape by an annular projection 24d, which is formed in the bottom end of the slot forming body 2 4 is, and a cutout 25d is provided in the bottom end of the channel-forming body 25. 30th

The inner end of the upper channel 33 defines an upwardly extending third branched slot 39 through an annular protrusion 25e formed on the upper part of the bottom end of the channel formation body 25 and the lower end of the channel formation body 26.

The slot 2 7 for the primary cooling is branched off through this Slots 37, 38 and 39 are formed.

The upper end of the uppermost channel formation body 26 is provided with an annular projection 26e, which extends along an inside Bore extending upward, which includes the wall 26 d of the channel forming body 26, and forms a channel 41 with the cross-section of an inverted L at its outer periphery, communicating with the opening 14, in Cooperating with an annular wall 40a extending from a support ring 40 which protrudes into the inner end surface of the upper housing 10 is fitted there opposite. Further the upper end of this channel 41 is provided with a slot 42 with an open top for secondary cooling.

At the top of the support ring 40, a second slot-forming body 43 is attached for changing the direction of the slot 42 blown out cooling air. This will now be described with reference to Figures 4 to 6 below.

The upper surface of the upper support ring 40 is provided with grooves of rectangular shape as seen from above extending in the radial direction, and each groove 44 slidably takes a substantially L-shaped slide bar 45 having an outer end portion 4 extending upward 5a on.
25th

The upper surface of the inner end portion of each slide bar is fixedly attached to a horizontal air baffle 46a, which is made by cutting a sheet material into an arcuate shape having a certain width, its both end parts being rounded, and the inner end part 45a of the slide rod 45 is provided with a roller 47, which is freely rotatable about a vertical axis.

Reference numeral 48 denotes an annular cam plate, the inner periphery of which is provided with arcuate or curved cam grooves 4, which are of sufficient width for the sliding and rotatable reception of the respective rollers 4 7 and with the inner peripheral surface under one

cut a predetermined angle, and this cam plate 48 is slidably mounted on the support ring 40.

If, as shown in FIG. 5, the slide bars 45 in the corresponding grooves 44 are added and the rollers 47 are loosely received in the corresponding cam grooves 4 8a, the two ends of each air baffle are located 4 6a with those of the adjacent plates 46a in overlap to form a ring 46 as a whole.

At 49 an annular cover is designated, and you Groove part 4 9a with the cross section of an inverted U is fitted on the outer circumferential surface of the cam plate 4 8, and an annular gap 50 is between the lower surface of the annular cover 4 9 rubbed its inner Circumferential wall and the upper surface of the support ring 4 0 next to its inner circumferential wall formed around the air baffle plates 50 to push out of there and pull in there.

The outer peripheral surface of the annular cover 49 has four outwardly extending handle bars 51 there around so that the cam plate 48 can be rotated about a vertical axis with these handle bars 51.

Now, the following is the handling and operation of the air ring for film blow molding as described above Arrangement according to the invention explained.

In order to remove the unevenness in the film thickness, the lower case 8 of the air ring main body 7 is detached from the rotor 4 rotated by means of the punch 1 and the arms 5.

Next, high temperature molten thermoplastic resin is applied to the die lip 1a 1 extruded and formed into a tubular, thin film or a bladder 3 is formed, and the diameter of the bladder 3 is expanded and expanded by the inward of the Ste.mpel 1

-13-blown cooling air as soon as bubble 3 goes up.

Regarding the outer surface of the bladder 3 is meanwhile the cooling air introduced into the cooling ring main body 7 from the air supply lines 22 through an annular, the Cooling flow straightening valve unit 15 is aligned, and after passing through opening 14 it becomes partial blown towards the bladder 3 out of the slot 42 for the second cooling activity, by means of the upper passage 41, while the remaining cooling air enters the channels 31, 32 and through the through holes 34, 35 and 36, and is blown out of the slot 2 7 or the branched slots 37, 38 and 39 to the part of the bladder 3 next to the Cool stamp 1.

With this cooling of the bladder 3, the direction of the slits 37, 38 and 39 that are branched off from the parts changes cooling air blown out next to the punch 1, as indicated by arrows (a), (b) and (c).

Furthermore, the mutual distances between the channel-forming Bodies 23, 24, 25 and 26 adjustable in that the threaded parts 23c, 24c and 25c in the Clockwise or counterclockwise.

If one wishes to increase the cooling of the lower part of the bladder 3, the wind pressure of the branched slot 37 becomes increases, while if one wants to increase the cooling of the upper part of the bladder 3, the wind pressure of the branched off Slot 3 8 is increased by adjusting the axial positions of the channel-forming bodies 23, 24, 25 and 26.

When a smaller diameter punch is used, the distance between the slot 27 and the punch 1 increases but it is possible to have the cooling air effectively reach the bladder 3 by applying the wind pressure of the lower branched slot 3 7 increased.

Conversely, if a punch 1 of larger diameter is used, the distance between the slot 2 7 and the Bladder 3 so small / that air blowing directly onto bladder 3 at high speed causes a pressure reduction in the Bubble 3, which is undesirable in the molding process. In such a circumstance it is possible to reduce the wind pressure to decrease at the lower, branched slot 37 and to increase the wind pressure of the upper branched slot 3 8. Since the upper branched slot 38 has an upwardly directed air outlet, the cooling air hits at high speed the bladder 3 at an oblique angle and does not deform the bladder 3.

Therefore, the cooling zone of the bladder 3 can be freely determined by the wind speeds of the slot 27, inclusive a plurality of slots having different outlet angles are appropriately combined or selected will.

Even if, depending on the size of the stamp 1, the type of Resin, the wall thickness of the bladder, etc. in a conventional manner, the cooling zone changes significantly, but it is limited because only one slot has been used and the slot is through another with a different diameter to substitute for other shape requirements. According to the invention, however, the slot can be adapted to different molding conditions can be adjusted in a very simple manner.

You also have the channel-forming bodies 23, 24, 25 and 26 given the shape of an inverted truncated cone in order to adapt it to the shape of the bladder 3.

As soon as the air blown out of the branched slots 37, 3 8 and 3 9 through the Stroking air channels formed between the bladder 3 and the channel forming bodies 26 becomes more definite Time a Venturi effect is generated, and the otherwise unstable bubble 3 is sucked radially outwards with the result

nis that the bladder 3 is effectively formed, wherein a fixed shape is held without fluttering or swaying.

Thus, wrinkles, sagging parts, uneven wall thickness and other problems are due to the flutter or The fluctuation of the bladder is greatly reduced, and a good quality product is obtained. Especially in mass production, where a fairly large volume of cooling air is required, the increase in wind pressure is common deformation and fluttering of the bladder 3 to such an extent that the molding process becomes impossible.

However, the larger the volume of the cooling air, the more the Venturi effect is promoted according to the invention, and the The stability of the bladder 3 is improved. The reason to point the outlet of the upper branched slot 3 9 upwards, lies in promoting this Venturi effect.

As seen in Figure 4 is in the second slitting ring body 3, the inner diameter of the ring 46 can be changed by turning the handle bar 51 around a necessary Angle rotates.

When in other words the ring 4 6 is in its most inwardly protruding state, the cooling air from the slot 42 impinges on the lower surface of the ring 46 and cools as indicated by an arrow (d) is indicated, the lower part of the crystallization limit (f). the bladder 3.

When the ring 46 has been withdrawn into the annular cover 49, the cooling air blows out of the slot 42 upwards as indicated by an arrow (e) ₇ and can cool the upper part of the crystallization limit Cf) of the bubble 3. In other words, by moving the slit formation body 43, the cooling zone of the bladder 3 can be moved.

The valve unit 15 for directing the air jet in the channel 7a of the air ring main body 7 in the above described embodiment consisted of a ring main body through which a plurality of axially extending, circular holes 15a was provided, but the annular main body may be with honeycomb holes or Grooves instead of circular holes may be provided. It is also possible to use a variety of thin plates, radially extending, to be arranged at the same distance on the circumference or to provide a porous ring body in the passage.

Instead of the slit-forming body 28 and 43 can also be a Plurality of plate belts 55 are provided curved shape, the inner circumference of a ring 52 by means of a Pin 53 at one end of each apron belt 55 are pivotable and longitudinally by means of a connection 54 at the other end a circular path are movable to form an iris diaphragm 56, which the opening of the slit with an inscribed Circle of each apron conveyor 55 can close.

Figure 9 shows another embodiment of this invention. According to this embodiment, a desired number of rings 58a, 58b, and 58c are on the uppermost channel formation body 26 attached to the opening area of the central, continuous Hole 42 to decrease. These rings 58a, 58b and 58c are of different diameters and are complementary inner and outer shouldered surfaces 57 and 57a provided such that adjustable means to reduce the opening area of the center the hole 42 can be obtained by making a desired number of these rings with suitable inner and outer Design and diameter is attached.

This feature is useful for adjusting the air ring according to the invention on extruder dies of different diameters. Especially when the punch diameter is small it is necessary that the air velocity for the cooling air is high enough to reach the bladder,

as the distance the air must sweep before reaching the bladder increases. The increase in airspeed tends to create turbulence especially in the area immediately downstream of the 5 is the uppermost end 26e of the uppermost channeling ring body 26, and this turbulence of the cooling air is extremely undesirable, as it causes the bladder to flutter or sway and the cooling becomes uneven. Therefore the adjustable means 58 for restricting the area of the central through hole are both very effective in the restriction or limitation of the opening area of the central, through hole as well as reducing the occurrence of turbulence in the cooling air.

According to the description, a free Selection of the optimal cooling zone in connection with the change in the bubble diameter can be offered (blow-up ratio) , and according to the invention, the molding speed can be achieved by providing a slitting body with a adjustable opening gap can be increased at the opening of the slot from which the cooling air flows out, so that the cooling zone of the bladder can be movable.

Further, the cooling position besides the crystallization limit must be adjusted extremely finely in order to increase the transparency of the tubular thin film in the blow molding method for low density polyethylene (L-LDPE), and the air ring according to the invention can meet this requirement exactly.
30th

By creating vertically spaced slots in the air ring and allowing the directions of the Changing the cooling air flow is the air guiding effect for reducing the flutter or fluctuation of the bias improved, and the cooling effect when wrapping the bladder is favored with the result that the adhesion between the thin film (congestion or blocking) is prevented, and the production speed can be increased.

Claims (11)

Dr. Dieter Weber Klaus Seiffert Pinemanwnhc p
P.O. Box 0) 45 6200 Wi D-6200 Wiesbaden 1 Telephone O O] 2) '87UTU (I in Main (17 l \ '. i iKC HmikilJrf-diiorHniik -V .. W ιι · ^ | .ΐ. · ίι · ΐι Komii Ni-.27 (i807 () (l (Η1 ^. ~ | () ΜΙιιι · ι> um, .η, January 5, 1984 S / st Tomi Machinery Manufacturing Co., Ltd., 4-16-4 Koyama, Shinagawa-ku, Tokyo, Japan Air ring for film blow molding Priority: February 10, 1983, Japan No. 58-19635 Claims [1./Air ring for film blow molding, which involves cooling by blowing cooling air out of a horizontal annular slot after the film is obtained through a punch is extruded or extruded, characterized in that an air ring main body from consists of a hollow ring body and is connected to an air supply line, a ring body defining a slot is essentially coaxial with the main body of the air ring and is arranged in it to form a primary air outlet, the horizontal ring slot for cooling the formed film is provided by blowing cooling air, a channel the air ring main body with the primary Air outlet and connects to another body forming a louver and that the duct in the latter the slit-forming body is branched into a plurality of slits for blowing the cooling air up the extruded film from more than one direction. 2. Air ring according to claim 1, characterized in that the annular body forming the slot consists of at least two there is frustoconical hollow bodies attached to their upper other ends are adjustable threaded so that an opening gap, which through the lower free ends of the frustoconical hollow body is formed / is adjustable by changing the relative Axial positions of the hollow bodies. 3. Air ring according to claim 2, characterized in that the ring body forming the slot consists of four frustoconical ring bodies which are further adjustable at their upper ends with thread in such a way that three opening gaps which are formed at their lower free ends are independently adjustable are. 4. Air ring according to claim 3, characterized in that the free ends of at least three lower frustoconicals Annular bodies are provided with horizontal extensions that extend inward towards the center. 5. Air ring according to one of the preceding claims, characterized in that the primary channel, which i is formed by the annular body forming the slot, is variable in cross-section in that the uppermost frustoconical annular bodies relative to the air ring main body is adjustable. 6. Air ring according to claim 5, characterized in that the opening gaps of the free ends of the frustoconical gene ring bodies are arranged such that they form opening gaps, the substantially different starting angle to have. 7. Air ring according to claim 6, characterized in that the outermost free ends of the frustoconical hollow body are provided with axially protruding, annular projections for controlling the exit angle the air flow that comes out of the exit gaps at the free ends of the frustoconical ring bodies. 8. Air ring according to claim 7, characterized in that the annular body forming the slot is fixed to the punch is mounted so that they are integrally rotatable. 9. An air ring according to claim 8, characterized in that an annular cover is provided on an upper end of the air ring main body is provided and is provided with a plurality of horizontal, arcuate plates which extend toward the molded film and come out of the air ring main body so as to be movable and form a ring shape as a whole. 10. Air ring according to claim 9, characterized in that the air ring main body consists of an upper case, a lower case and a side case, the side case is connected to the air supply line, while the lower and the upper housing on which the slot forming ring body are attached, and that an air seal between the side housing and a unit is provided, which consists of the upper and the lower housing, so that the upper and lower housing with respect to the side housing can be rotated without the airtight State of the air ring main body is lost. 35 11. Air ring according to claim 10, characterized in that the channel connecting the air ring main body with the ring body forming the slit with one of the -A- Air jet straightening ring body is provided, which is provided with a plurality of axially extending, continuous Is provided with holes.