DE20117404U1 - extrusion plant - Google Patents

Description

Extrusion plant

The invention relates to an extrusion system for producing, in particular, foam films, consisting of at least one extruder, an extrusion tool and a calibration device, wherein at least the two components extrusion tool and calibration device are arranged downstream of the extruder in the extrusion direction and are arranged on a component carrier.

In the commonly known extrusion systems for foam film, a tool and a cooling mandrel follow the extruder in the direction of extrusion; if necessary, a and/or can also be connected downstream. In addition, a static mixer, a pump, a filter and a homogenization zone can be connected downstream of the extruder.

For an optimal process flow, it is necessary that all components are aligned in one line. For this purpose, the components are arranged on an adjustment system and can be adjusted using four adjustment screws attached to the ends of the units. However, different systems are often used for the individual units, which makes it difficult to exchange them with one another.

The object of the invention is to avoid these disadvantages and to offer a device which can be used universally, whereby the adjustment should be simplified.

The solution to the problem is characterized in conjunction with the preamble of claim 1 in that the component

FGOOlDE Oct-01

carrier is modular in design and consists of at least one adjustment system and one system carrier, whereby the component carrier can be adjusted in at least one axis via the adjustment system or the system carrier.

This means that an identical component carrier structure is selected for all units.

The adjustment system is preferably constructed from two, preferably trapezoidal, plates that are arranged on a movable system carrier, each plate being adjustable in at least one axis using two adjustment means. Adjusting screws or any other suitable device such as a piston/cylinder unit or spindle can be used as adjustment means. However, a pneumatic-hydraulic spindle, a lever system consisting of, for example, a joint with a screw or a magnetic or electrical adjustment can also be provided. This means that the components can be mounted on a uniform component carrier and easily adjusted.

Advantageously, the system carrier of the component carrier is a movable frame and can be moved via a guide system. It can therefore be easily positioned behind the extruder and stored in a suitable location without dismantling. The guide system is a rail system that is made up of wheels or rollers with a complementary guide profile. However, it is also conceivable to use a system consisting of a linear or other guide system that is fixed

; · · F G 001 DE Oct-01

-3-

anchored to the ground. This allows for very precise positioning of the individual units.

In order to compensate for the increased costs, it is proposed to equip the adjustment system with a guide system and to make the movable system carrier adjustable in at least one axis.

All downstream components or units such as a cutting knife for cutting to length or an air ring, as well as a cooling ring, can be mounted on this proposed component carrier; of course, this also applies to a pull-off device.

In the drawings, an embodiment of the invention is shown schematically, it shows

Fig. 1 an extract of the extrusion line,

Fig. 2 the component carrier,

Fig. 3 four variants of the guidance system and

Fig. 4 an alternative design

Figure 1 shows a schematic of an extrusion system 1. In the extrusion direction, the extruder 2 is followed by an extrusion tool 3 and a calibration device 4. In order to extrude a usable film, all components must be arranged in a line after the extruder 2. For this purpose, the components are mounted on a component carrier 5. Both component carriers 5 are modular.

F G 001 DE Oct-01

-4-

constructed and can be individually adjusted to each component. Each component can be precisely aligned using an adjustment system 6. The adjustment system 6 consists of two plates 10, the position of which is changed using an adjusting device 8, in this case an adjusting screw. In the simplest case, the two plates 10 are not connected to one another. If this is necessary, the connection is made using profiles attached above or between the plates 10. If possible, all plates 10 have a trapezoidal shape, which can, however, be adjusted by splitting the tubular film into 2 individual films and by using cooling rings for PE films.

Figure 2 shows the component carrier 5 with the adjustment system 6, which consists of the trapezoidal plate 10 and is connected to the system carrier 7 via the adjusting screws as adjustment means 8. The system carrier 7 is guided via a guide system 9 in the floor. In Figure 2, a roller/rail system is used as the guide system. In order to prevent the system carrier from jumping out of the guide system 9, it is proposed to use a sliding shoe system on a rail profile. If a certain force distribution is required, any other conceivable system suitable for guidance can be used. Figure 3 shows some examples of such a design.

The exemplary embodiment 3a shows a roller/rail guide as used on the component carrier according to Figure 2, example 3b shows a sliding shoe system in which the rail is completely gripped and thus jumping out is prevented. Another variant of a profile system is shown in Figures 3c and 3d. This guide

F G 001 DE Oct-01

-5-

systems also allow the component carrier to slide smoothly, whereby the design according to Figure 3d can absorb forces in several directions. This also effectively prevents the component carrier from tipping or rocking. Figure 4 shows an alternative design, in which a height adjustment is integrated into the rollers of the system carrier 7 so that the component can be moved on a rail system. A separate adjustment of the plates (not shown in Figure 4) can be omitted.

These profile systems are very well suited to form the entire component carrier.

The proposed modular design of the component carrier enables easy adaptation of the components to the respective extruder and is universally adjustable for each unit.

F G 001 DE Oct-01

List of reference symbols;

1 extrusion line

2 extruders

3 Extrusion tool

4 Calibration device

5 component carriers

6 Adjustment system

7 System carrier

8 Adjustment system adjustment tools

9 Guidance system

10 Plate of the adjustment system

.·: : : : .· :.:.: ::.:. : : : f g ooi de oct-oi

Claims (14)

1. Extrusion plant for the production of foam films in particular, consisting of at least
an extruder ( 2 ),
an extrusion tool ( 3 ) and
a calibration device ( 4 ),
wherein at least the two components extrusion tool ( 3 ) and calibration device ( 4 ) are arranged downstream of the extruder ( 2 ) in the extrusion direction on a component carrier ( 5 ),
characterized in that
the component carrier ( 5 ) is of modular construction and consists of at least one adjustment system ( 6 ) and one system carrier ( 7 ), wherein the component carrier ( 5 ) can be adjusted in at least one axis via the adjustment system ( 6 ) or the system carrier ( 7 ). 2. Extrusion system according to claim 1, characterized in that the component carrier ( 5 ) can be used for each of the components ( 3 , 4 ). 3. Extrusion plant according to claim 2, characterized in that the adjustment system ( 6 ) is constructed from two, preferably trapezoidal plates ( 10 ) or profile frames, which are arranged on a system carrier ( 7 ), wherein each plate ( 10 ) or profile frame is variable in at least one axis via two adjusting means ( 8 ). 4. Extrusion plant according to claim 3, characterized in that the adjusting means ( 8 ) are adjusting screws. 5. Extrusion plant according to claim 3, characterized in that the adjusting means ( 8 ) is a piston/cylinder unit. 6. Extrusion plant according to claim 3, characterized in that the adjusting means ( 8 ) is a pneumatic-hydraulic spindle. 7. Extrusion plant according to claim 3, characterized in that the adjusting means ( 8 ) is a spindle. 8. Extrusion plant according to claim 3, characterized in that the adjusting means ( 8 ) is a lever mechanism, preferably consisting of a joint and a screw. 9. Extrusion plant according to one of claims 1 to 8, characterized in that the system carrier ( 7 ) is movable on a guide system ( 9 ). 10. Extrusion plant according to one of claims 1 to 9, characterized in that the guide system ( 9 ) is formed from a rail system of wheels or rollers with a complementary guide profile. 11. Extrusion plant according to one of claims 1 to 9, characterized in that the guide system ( 9 ) is a linear guide system. 12. Extrusion plant according to one of claims 1 to 9, characterized in that the guide system ( 9 ) can be folded away. 13. Extrusion system according to at least one of the preceding claims, characterized in that a cutting knife for cutting to length is arranged on a component carrier ( 5 ) according to one of claims 1 to 12. 14. Extrusion plant according to at least one of the preceding claims, characterized in that all components ( 3 , 4 ) downstream of the extruder ( 2 ) are arranged on a single system carrier ( 6 ) according to one of claims 1 to 12.