DE20005026U1 - Nozzle plate with conical projection for underwater pelletizers - Google Patents

Description

Company BKG Bruckmann & Kreyenborg Granuliertechnik GmbH, Coermühle, 48157 Münster

"Nozzle plate with conical projection for underwater granulators" 5

The innovation relates to a nozzle plate with a conical projection for use in underwater granulators, whereby the nozzle plate is equipped with heating elements and arranged in front of a cutting chamber.

Underwater granulators for producing pellets from plastic by using an extrusion nozzle with openings through which a polymer melt is fed into a cutting chamber and there extruded through a cutting head and caught by knife blades which are mounted on a rotating knife body.

be attached are generally known. Such an arrangement is described, for example, in US-PS 41 23 207.

In the nozzle plates used so far, both the base body of the nozzle plate and the displacer body

the screwed-on conical projection made of solid material, namely metal.

This arrangement means that the entire nozzle plate and cone projection material, which is used for the tempering of the

Areas where the extrusion openings are located do not need to be heated. The amount of heat that flows to the center of the nozzle plate and the cone projection is therefore no longer available for the important area where the extrusion openings are located.

The innovation is based on the task of creating an intensive and above all more uniform temperature control of the area of a nozzle plate in which the extrusion openings are located, whereby the invention is preferably used for

electrically heated nozzle plates should be used.

This problem underlying the innovation is solved by the teaching of the main claim and the subordinate claim 2.

Advantageous embodiments of the innovation are described in the

Subclaims explained.

In other words, it is proposed that the heat loss occurring in the area of the center of the nozzle plate and/or the cone projection be reduced by

A cavity is created in the inner area of the nozzle plate and the cone projection, i.e. in this area the two components are turned out. Material that is no longer present does not require any amount of heat for tempering and the amount of heat applied is fully concentrated on

the crucial area of the cone projection and the nozzle plate. The amount of heat saved is thus concentrated on the area in which it is required to maintain the flowability of the polymer melt.

In addition, the new proposal means that the air enclosed in the center of the nozzle plate and the cone projection now acts as an insulator, so that the insulation disks usually used in the center on the cutting chamber side can be omitted, which would otherwise be necessary

are necessary to avoid heat losses that may occur here.

Further optimization may be achieved by filling the hollow areas provided for in the innovation with insulating properties.

For example, evacuating the entire hollow area or parts of the hollow areas can provide further insulation. By creating a vacuum inside the plate, the insulation effect is further enhanced. The cavity inside the nozzle plate can be divided into chambers

divided into chambers, whereby not all chambers need to be evacuated

If, for example, the end wall is to be connected to the nozzle plate in a material-locking manner, this is preferably done by soldering and this in turn preferably under vacuum, so that the evacuation of the hollow area is automatically effected. A supporting wall inside the hollow area of the

The nozzle plate can support the end wall from the inside so that when a vacuum is created inside the nozzle plate, a curvature of the end wall is excluded.
10

It is also possible to introduce other insulating materials, regardless of whether they are solid, liquid or gaseous.

Examples of the innovation are explained below using the drawing. The drawing shows in

Fig. 1 shows a first embodiment of an inventive

appropriate design with hollow nozzle plate and hollow cone projection, in

Fig. 2 an arrangement according to the innovation, in which the

End wall, which is directed towards the cutting chamber, is designed as an insert plate and in

Fig. 3 shows a modified embodiment.

The drawings show a nozzle plate 1 which has

has a large number of extrusion openings 2 distributed around its circumference. On the outside of this nozzle plate, a contact wall 3 is provided, which preferably serves to attach an electrical heating element. On the side of the nozzle plate 1 directed towards the supply of the polymer melt, a

A conical projection 4 is provided, which in the embodiment shown is connected to the nozzle plate by means of a thread 10. A closing wall 8 is arranged opposite the conical projection 4, which is directed towards the cutting chamber (not shown in the drawing) and is mounted on the outer circumference in the

-A-

A heat transfer ring 5 can be seen in the area of the extrusion openings 2.

The actual nozzle plate 1 is hollow in the inner area 6, whereby in the embodiment shown in Fig. 1 the wall 8 of the nozzle plate 1 directed towards the cutting chamber (not shown) is formed from the same material as the nozzle plate. In the arrangement according to Fig. 2 the wall of the nozzle plate 1 directed towards the cutting chamber (not shown) is formed as an insert plate 9 made of

which is fixed to the nozzle plate 1 by a thread 11.

In the arrangement according to Fig. 1, the required stability of the nozzle plate is easily achieved by the end wall

8, while the arrangement according to Fig. 2 enables a simplified manufacture of the hollow, inner region 6 of the nozzle plate.

The actual conical projection 4 is in both shown

Embodiments according to Fig. 1 and Fig. 2 are fixed to the nozzle plate 1 by means of a thread 10 and are hollow in their inner region 7. What is not shown is that the conical projection 4 can also be made of solid material, i.e. is not hollow.

In the embodiment shown in Fig. 3, both the conical projection 4 and an end wall 12 are connected to the actual nozzle plate 1 by means of a material connection, for example by soldering. In addition, in the inner area 6 of the

A support wall 14 is provided on the nozzle plate 1, which is formed from the same material as the nozzle plate and which, in conjunction with the end wall 12, creates the two hollow areas 6a and 6b. If the end wall 12 is now connected to the nozzle plate 1 by soldering,

where soldering is carried out under vacuum, for example,

•t

·

·

-5-

At the same time, the hollow areas 6a and 6b are evacuated, thereby achieving even better thermal insulation.

The same applies to the hollow area 6 between the support wall 14 and the conical projection 4 when this conical projection 4 is connected to the nozzle plate 1 under vacuum. A vacuum then prevails both in the hollow area 6 and in the hollow area 7 of the conical projection 4. In the embodiment shown in Fig. 3, the support wall 14 rests against the rear side of the support wall 12 and supports it, which in particular

This can be particularly advantageous if there is a vacuum in areas 6a and 6b.

What is not shown is that additional solid, liquid or gaseous insulation materials are introduced into all hollow areas.

in order to further reduce heat losses.

It should be noted that in the embodiment according to Fig. 3, even if the end wall

is materially connected to the nozzle plate 1, the conical projection 4 can be screwed into the nozzle plate, so that combinations are possible.

Claims (10)

1. Nozzle plate with conical projection for use in underwater granulators, wherein the nozzle plate is equipped with heating elements, characterized in that the nozzle plate ( 1 ) is hollow in the inner region ( 6 ). 2. Nozzle plate with conical projection for use in underwater granulators, wherein the nozzle plate is equipped with heating elements, characterized in that the conical projection ( 4 ) is hollow in the inner region ( 7 ). 3. Device according to claim 1 and 2, characterized in that both the nozzle plate ( 1 ) and the conical projection ( 4 ) are hollow in their inner regions ( 6 , 7 ) and the inner regions ( 6 , 7 ) are connected to one another. 4. Nozzle plate according to one of the preceding claims 1 to 3, wherein the nozzle plate is arranged in front of a cutting chamber, characterized in that the end wall ( 8 ) of the nozzle plate ( 1 ) directed towards the cutting chamber is formed of the same material as the nozzle plate ( 1 ). 5. Device according to one of the preceding claims 1 to 3, wherein the nozzle plate is arranged in front of a cutting chamber, characterized in that the end wall ( 9 ) of the nozzle plate ( 1 ) directed towards the cutting chamber is designed as an insert plate. 6. Device according to claim 1, characterized in that the conical projection ( 4 ) consists of solid material. 7. Device according to claim 5, characterized in that the end wall ( 12 ) directed towards the cutting chamber is materially connected to the nozzle plate ( 1 ). 8. Device according to one of the preceding claims, characterized in that a supporting wall ( 14 ) is provided in the inner region ( 6 ), which rests against the rear side of the end wall ( 8 , 9 , 12 ). 9. Device according to claim 8, characterized in that the supporting wall ( 14 ) is formed of the same material as the inner wall of the hollow region ( 6 ). 10. Device according to one of the preceding claims, characterized in that the hollow regions ( 6 , 6a , 6b and 7 ) are provided with fillings having insulating properties.