CZ302894A3 - Process and apparatus for cooling a hose of thermoplastic material melt, extruded from a foil blowing head - Google Patents

Abstract

In a process for cooling the parison of thermoplastic melt extruded from a film blowing head, cooling air is blown out in the direction of the parison from at least one cooling ring surrounding the annular die gap of the blowing head. To be able to increase the output of blown-film installations by using colder cooling air, the parison is blown with a primary cooling-air stream at a temperature below 0 degrees C and this cooling-air stream is enveloped by a secondary air stream of dry air at a temperature of above 0 degrees C.

Description

Method and apparatus for cooling a melt hose of a thermoplastic plastic extruded from a film blowing head

Technical field

The invention relates to a method of cooling a melt hose of a thermoplastic plastic extruded from a film blowing head, in which it blows from at least one cooling ring with an annular exit slot that surrounds the blow head nozzle slot or hose cooling air in the direction on or parallel to the hose .

BACKGROUND OF THE INVENTION

The performance of the film blowing apparatus can be increased by increasing the amount of cooling air blown per time unit and also by lowering the temperature of the cooling air.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method of the kind mentioned above, by means of which colder cooling air can be used to increase the performance of a film blower.

The task is solved in a method of this kind in that the hose is blown by a primary cooling air stream below 0 ° C and that the cooling air stream is enveloped by a secondary dry air stream above 0 ° C. film blowing temperature cooling air can in the area 'where'se' come together or swirl '.....

cooling air with ambient air, condensation of water vapor from the outside air can cause droplets, snow or ice crystals to precipitate on the extruded hose or blown foil bubble where they can cause damage. The danger of condensation from outside air is particularly great when the primary cooling air flow is deeply deprived, ie has a temperature of minus 10 ° C or lower. In order to avoid the risk of unwanted condensation of water from the outside air when using very cold cooling air, the primary primary cooling air stream encompasses a secondary air stream consisting of dry air above 0 ° C. air flows around the cooling air and prevents the cold cooling air stream from coming into contact with the ambient air while it is still at a temperature so low that water condensation occurs in the ambient air. This secondary air stream first separates the cooling air stream from ambient air so that the cooling air stream cannot cause moisture condensation from the secondary air stream because .....

it is made up of dry air and also does not condense any moisture in the boundary area between the secondary air and the ambient air, since a dry secondary air stream can absorb some moisture from the ambient air and mix the cooling air stream and its surrounding secondary air stream with ambient air only when the cooling air stream has heated to such an extent that it can no longer cause condensation of moisture from the ambient air to a dangerous extent. very low values. Preferably, the primary cooling air stream has a temperature in the range of minus 10 ° C to minus 25 ° C.

The temperature of the secondary air stream should be chosen such that the cooling air stream is effectively protected from the ambient air and the formation of condensation between the secondary air stream and the ambient air is avoided. 15 ° C and preferably about 10 ° C.

In a further development of the invention, it is envisaged that the secondary air stream is split off from the primary stream and heated to a higher temperature of the secondary stream. A split of the air from the primary stream streams loses some of the cooling air. air that meets the demands placed on it.

A blow head and cooling ring apparatus for carrying out the method of the invention is characterized in that the lower cooling ring with an annular outlet slot is predicted for a cold primary cooling air flow and a cooling ring with an annular outlet slot lying above it for a warmer secondary airflow. are arranged such that the warmer secondary air stream concentrically envelops the internal cooling air stream.

By another embodiment of the device according to the invention, it is envisaged that ducts for cleaved portions of the cold primary cooling air stream and supplying the separate cooling air stream to the annular outlet slot of the warmer air stream are envisaged and that at least one wall delimiting the outlet slot of the warmer air stream is heated. through the wall, the split cooling air stream is heated to the desired temperature of the secondary air stream.

Preferably, the ducts for splitting off a portion of the cooling stream form bores through the ring separating the two air streams.

In another embodiment of the invention, it is envisaged that the top wall delimiting the warmer air exit slot is formed by a ring provided with heating elements.

According to a further development of the invention, it is envisaged that the film blowing head is provided with a cylindrical part of the tube enclosing the extruded hose, having a heating element and a perforated wall. The heated and apertured cylindrical wall simultaneously forms a heating grille. air being ambient. it dries the air so much that no water condenses from it.

It is expedient if the cylindrical perforated tubular part is made of a good thermally conductive material, for example copper. According to a preferred embodiment, it is envisaged that the annular element heating the secondary air flow is divided into annular sectors, the temperature of which can be separately controlled. In this way, the temperature profile surrounding the extruded film hose can be influenced.

According to a further preferred embodiment, it is envisaged that the annular outlet slot of the cold primary air stream is divided into individual outlet segments whose outlet cross-sections can be individually controlled. Accordingly, by correspondingly controlling the outlet cross-sections, a desired temperature profile can also be created.

Overview of the drawings

The invention will now be described in more detail with reference to the drawings.

Giant. 1 partial longitudinal film heads, rust first shape design blowing Fig. 2 partial longitudinal film heads; and rust second shape design blowing Fig. 3 partial longitudinal rust third shape design blowing

foil heads.

DETAILED DESCRIPTION OF THE INVENTION

1 shows a blowing head of a foil 1 of conventional construction provided with an annular gap of the nozzle 2 from which a plastic melt hose exits and is inflated into a foil bubble from which a flat foil hose is contracted by conventional squeeze rolls.

Mounted on the outer ring 6 of the blow head 10 above the insulating gap 15 is a first cooling ring of preferably poorly conductive material which, together with the second cooling ring 7, delimits the outlet slot 8 for the heavily cooled primary cooling air stream directed substantially. In the direction of the extruded film hose, an annular disc chamber 8 is provided upstream of the outlet slot 8, to which dry cold cooling air is supplied through the vertical inlet 10.

The cooling ring 7, which is screwed in the illustrated manner with the central holding and dividing plate 11 of the external cooling unit 12, together with the upper cooling ring 13 forms an outlet slot 14 of warmer dry secondary air, also directed substantially towards the extruded foil hose. the slot 14 has a larger diameter than the annular slot 2 of the primary cooling air, so that when viewed from above, the annular outlet slot 14 surrounds the annular inner outlet slot 2 of the outlet slot 14; inlet 17 of warmer dry secondary air.

According to the embodiment of Figure 2, the blow head 2 corresponds to the embodiment of Figure 1. On the outer ring 6 of the blow head 1 is fixed with an insulating gap 21, the first outer cooling ring 20 of poorly thermally conductive material. the second cooling ring 22 has an annular outlet slot 22 of strongly cooled cooling air, following the direction of the extruded foil hose 2. On the cooling ring 22, a third ring 24 is provided with heating elements 25 which together with the central cooling ring 22 delimits the outlet slot 26 extruded tubular film 2 ^«V Y ^with lable gap 26 upstream annular chamber is an aperture 27 passing through the cooling ring 22 is connected with an annular chamber 28 which is inside the exit slot 23 is fed heavily chilled primary cooling slots 23 and vzduch.Výstupní 26 are arranged concentrically to each other in the same manner as the exit slots, in FIG. 1.

Through the heated ring 24, the cold air cleaved through the openings 27 from the cold primary air stream is heated, so that a warmer air stream exits from the annular slot 26, enveloping the cooling air stream exiting the annular slot 23.

The embodiment according to FIG. 3 differs substantially from the embodiment shown in FIG. 2 in that the upper ring 24 heating the split cooling air stream is provided with a cylindrical part 30 of a thermally conductive material, the jacket of which is provided with apertures 31 forming a sieve. a ring 32 provided with a heating element which heats both the cylindrical part 30 and the ring 24 is provided.

According to the principle of the jet pump, the openings 31 are sucked in by the concentric air streams emerging from the annular slots 23 and 26, which are heated and dried, so that the air streams which mix over the cylindrical work at their temperatures. .

Claims (12)

A method of cooling a melt hose of a thermoplastic plastic extruded from a film blow head, wherein cooling air is blown from at least one annular slit nozzle of the blow head or a circumferential cooling ring hose with an annular outlet slit in a direction towards and / or parallel to the hose; characterized in that the hose is blown through a primary cooling air stream below 0 ° C and that the cooling air stream is enveloped by a secondary dry air stream above 0 ° C. The method of claim 1 wherein the primary cooling air stream has a temperature in the range of minus 10 ° C to minus 25 ° C. Method according to claim 1 or 2, characterized in that the secondary air stream has a temperature in the range of 5 ° C to 15 ° C, preferably about 10 ° C. Method according to one of claims 1 to 3, characterized in that the secondary air stream is split off from the primary cooling air stream and heated to a higher temperature of the secondary air stream. Device for carrying out the method according to one of the claims 1 to 4, with a blowing head provided with cooling rings, characterized in that a lower cooling ring with an annular outlet slot of cold primary cooling air and a cooling ring with an annular outlet slot of a warmer secondary air stream is provided. / 6. The apparatus of claim 5, wherein conduits are provided to split off a portion of the cold primary cooling air stream and to introduce the split cooling air stream into the annular exit slot of the warmer air stream, and wherein at least one wall delimiting the exit slot of the warmer air stream. is heated. The device according to claim 6. 6. The method of claim 1, wherein the conduits are formed by apertures in a ring separating the flow of cooling air. Device according to one of Claims 5 to 7, characterized in that the upper outlet slot of the warmer air-delimiting wall is formed by a ring provided with a heating element. Device according to one of Claims 5 to 8, characterized in that the blow head is provided with a cylindrical part enclosing the extruded hose, which is provided with a heating element and a perforated wall. Device according to claim 9, characterized in that the cylindrical part is made of a thermally conductive material, for example copper. Device according to one of Claims 5 to 10, characterized in that the secondary air flow heating the annular stream is divided into annular sectors, the temperature of which can be individually controlled. Device according to one of Claims 1 to 11, characterized in that the annular outlet slot of the cold primary air stream is divided into individual outlet segments, the output cross-sections of which can be controlled individually.