GB2023485A

GB2023485A - Extrusion granulating apparatus for plastics melt and other materials

Info

Publication number: GB2023485A
Application number: GB7919677A
Authority: GB
Original assignee: Hermann Berstorff Maschinenbau GmbH
Current assignee: KraussMaffei Extrusion GmbH
Priority date: 1978-06-09
Filing date: 1979-06-06
Publication date: 1980-01-03
Also published as: SU890963A3; IT7921746V0; GB2023485B; JPS54161666A; CA1128270A; NL7904527A; FR2427891A1; JPS6311123B2; FR2427891B1; DE2825288A1; DE2825288B2; DE2825288C3

Abstract

A cutter shaft (7) mounting a multi-blade cutting implement (10, 11), bearing means (6, 8, 9) for the cutter shaft (7) and drive means (21) therefor are combined into a unit, which is mounted so that it can be swivelled about a resiliently deformable centering ring (17) adjacent the extrusion die plate (15), to adjust the parallelism between the cutter blades (11) and the die plate (15). Screw drives (25) preferably effect the adjustment which is permitted by the unit being movably mounted to an extrusion die part 3 at a wall 36, by spring loadings 29 at bolts 28. The parallelism is determined by a single revolution of a measuring instrument with a blade holder 10. Cooling air is delivered onto the blades 11 from a die space 20, via holes 18 through the ring 17. The blades 11 throw the granules onto a water film running down a wall 30, of a housing 37 which may be vertically displaced from the die plate 15 by hydraulic cylinders 38. <IMAGE>

Description

SPECIFICATION Apparatus for granulating plastics melt and other materials The invention relates to apparatus for granulating plastics melt and other materials.

Apparatus of this kind has been previously proposed comprising a granulating head having a cutting plate and a multiblade cutting implement mounted in front of the plate, and a housing surrounding the granulating head and having means for cooling and conveying away the granules chopped off.

Such apparatus is known from U.S. patent specification 3 317 957, but in such apparatus peripheral plane parallelism cannot be obtained between the cutting blades and cutting plate. If there are found to be different gaps between the individual cutting blades and the cutting plate as a result of manufacturing tolerances, there is no possibility of adjusting the blades to the plate. The plates can only be moved horizontally all together, and irregularities at one side cannot be dealt with.

According to the invention there is provided apparatus for granulating plastics melt and other materials, comprising a granulating head having a cutting plate and a multi-blade cutting implement cooperating with the cutting plate, a housing surrounding the granulating head and having means for cooling and conveying away the granules chopped off, in which a cutter shaft mounting the cutting implement and bearing means and drive means for the shaft are combined into a unit which unit is mounted so that it can be swivelled about a bearing surface adjacent the cutting plate to adjust the cooperation of the blades of the cutting implement with the cutting plate.

Preferably the bearing means comprises a bearing housing, bearings, a cutter shaft mounting blade holders and cutting blades fixed to the blade holders, a holding plate, an adjusting spindle and a guard ring.

The apparatus advantageously includes screw drives to effect swivelling adjustment of the cutter shaft, bearing means and drive means about the bearing surface, the screw drives being mounted on an outer sleeve and engaging the holding plate.

Thus those parts of the cutter shaft, bearing means and drive means which are combined as a unit can be swivelled and adjusted by means of the screw drives and this enables the distance between the cutting blades and plate to be adjusted so that it is constant around the whole periphery.

Differences in the spacing can be made apparent by fastening a gap measuring instrument with a scale onto a blade holder and making the blade holder describe one complete revolution.

The differences revealed by the reading can then be compensated for exactly by appropriate movement of the screw drives.

Advantageously the cutter shaft, bearing means and drive means are supported on a centering ring forming the bearing surface and are designed to be centered horizontally by the screw drives.

Preferably plane parallelism to about 0.01 mm is obtained between the cutting blades and plate regardless of any manufacturing inaccuracies. This can ensure a clean cut, all the blades having the same clearance in each position, and extremely little wear on the blades and cutting plate.

The invention is diagrammatically illustrated by way of example in the accompanying drawings, in which: Figure 1 is a longitudinal section through granulating apparatus according to the invention Figure 2 is a cross-section taken on line Il-Il of Figure 1; Figure 3 is a cross-section taken on line Ill-Ill of Figure 1; and Figure 4 is a cross-section taken on line lV-lV 'of Figure 1.

Referring to the drawings, granulating apparatus has an outer sleeve 1 with an insulating jacket 2 disposed around it. Guide passages 4 for material are provided in a guide sleeve 3. The sleeve 3 is clad with an insulating layer 5. A cutter shaft 7, mounted by bearings 8, 9, is disposed in a bearing housing 6. Blade holders 10 with blades 1 1 attached thereto are mounted on the lower enc of the cutter shaft.

At the upper end of the cutter shaft 7 parallel axial adjustment means are provided comprising an adjusting spindle 12 and a guard ring 13 to arrest the cutter shaft. The adjusting spindle 12 can be rotated by means of a lever 14, to provide a coarse height adjustment of the cutting blades 11 with respect to a cutting plate 15.

The cutting plate 15 is located at the underside of the granulator with apertures 16 therein through which the material to be granulated is extruded. The cutting plate 15 is fixed to the outer sleeve 1 by screws 15a (Figure 4) and to the guide sleeve 3 by screws 1 sub. The guide sleeve 3 is in turn fixed to a bearing by screws 1 7a, the bearing being formed by a resiliently deformable centering ring 17 with the bearing housing 6 supported on it Holes 18 are provided in the ring 17 and are directed towards the blades 1 1.

Cooling air is blown into a cylindrical space 20 between the bearing housing 6 and the insulating layer 5 through a plurality of connections 19 distributed around the periphery. At the centering ring 7 side of the space 20 the cooling air is forced through the holes 18 towards the cutting blades. The space 20 is closed at the top by an annular wall 36 with the connections 19 leading to it.

The cutter shaft 7 can be rotated by a motor 21 by way of an interposed coupling 22 to compensate for vertical displacement of the shaft 7, and the rotation is transmitted through the holder 10 to the blades 1 1.

The liquid fused plastics material is pressed through an adapter 23 by an extruder (not shown) attached to it, into the material guide passages 4 and from there to the apertures 16 in the cutting plate 1 5.

As a means of obtaining plane parallelism between the cutting blades 11 and the cutting plate 15, the following components of the granulator are combined into a unit so as to swivel together as such: The cutter shaft 7 with the blade holders 10 and cutting blades 11 attached to it, the upper and lower bearings 8 and 9 for the shaft 7, the bearing housing 6, an upper holding plate 24 fixed to the bearing housing 6, the coupling 22 connecting the cutter shaft 7 to the drive motor 21, and the adjusting spindle 12 with the guide ring 13, the drive motor 21.

The above listed components of the granulator, which are constructed as a unit, bear on the centering ring 17 by means of the bearing housing 6, are adjustable and can be swivelled to a limited extent about the resiliently deformable centering ring 1 7. The ability to swivel is provided by distributing a plurality of differential screw drives 1 5 around the periphery, the screw drives being joined to the outer sleeve 1 by holding means 26.

To enable the unit to swivel horizontally, apertures 27 are provided in the holding plate 24 to receive cheese head screws 28 the shanks of which are smaller in diameter than the diameter of the apertures 27. In this way the holding plate 24 can move horizontally to a limited extent. Plate springs 29 are disposed between the heads of the screws 28 driven into the guide sleeve 3 and the holding plate 24, and these springs compensate for expansion of the sleeve 3 in an upward direction.

Since the apertures 27 are larger than the diameter of the shanks of the screws 28, there is an appropraite adjusting path for the granulator components combined into a unit.

The granules chopped off are thrown outwardly in a radial direction by the centrifugal force of the cutting blades, and impinge on a surface 30 which is covered with a film of water overflowing a top edge 31 thereof. The film of water carries the chopped off granules downwardly into a granulating chamber 32, from which they can emerge through an outlet 33.

To enable the blades to be serviced, and particularly to enable differences in plane parallelism between the blades 11 and the cutting plate 15 to be detected, an outer casing 37 together with the surface 30 are mounted to be movable vertically by means of hydraulic cylinders 38 and a rod system 39. When the outer casing 37 is moved downwards, the cutting blades 11 and cutting plate 15 are freely accessible.

In order to find any differences in plane parallelism between the cutting blades 11 and the cutting plate 15, a measuring instrument carrying a scale is mounted on one of the blade holders 10 and allowed to revolve once with the holder. By observing the scale any inaccuracies in plane parallelism between the cutting blades and cutting plate are thus made apparent. According to the values obtained in this way, the screw drives 15 are adjusted (Figure 2), and absolute plane parallelism can be established over the whole periphery, that is to say, the granulator components which are combined into a unit are swivelled and adjusted about the centering ring 17 according to the differences in plane parallelism found.

Since the bottom end of the cylindrical bearing housing 6 is horizontally disposed, substantially or the same plane as the cutting surace, the gap between the blades 11 and cutting plate 15 does not vary when the temperature of the guide sleeve 3 differs from that of the outer sleeve 1. A heating cargridge 34 is preferably provided to heat the outer sleeve 1.

Claims

Apparatus for granulating plastics melt and other materials, comprising a granulating head having a cutting plate and a multi-blade cutting implement cooperating with the cutting plate, a housing surrounding the granulating head and having means for cooling and conveying away the granules chopped off, in which a cutter shaft mounting the cutting implement and bearing means and drive means for the shaft are combined into a unit which unit is mounted so that it can be swivelled about a bearing surface adjacent the cutting plate to adjust the cooperation of the blades of the cutting implement with the cutting plate.
2. Apparatus according to claim 1, in which the bearing surface is disposed substantially in the same plane as the cutting plane between the cutting plate and the cutting blades.
3. Apparatus according to claim 1 or claim 2, in which the bearing means comprises a bearing housing, bearings, the cutter shaft mounting blade holders and cutting blades fixed to the blade holders, a holding plate, an adjusting spindle and a guard ring.
4. Apparatus according to any one of claims 1 to 3, in which the drive means comprises a motor and a coupling to compensate for vertical displacement of the cutter shaft.
5. Apparatus according to any one of claims 1 to 4, in which the bearing surface is formed by a resiliently deformable centering ring.
6. Apparatus according to either of claims 4 and 5 when appendent to claim 3, including screw drives to effect swivelling adjustment of the cutter shaft, bearing means and drive means about the bearing surface, the screw drives being mounted on an outer sleeve and engaging the holding plate.
7. Apparatus according to claim 6, in which the screw drives are formed by a plurality of differential screw drives engaging the periphery of the holding plate.
8. Apparatus according to claim 6, in which the holding plate contains apertures to receive screws the shanks of which are of smaller diameter than the apertures to allow for horizontal displacement of the holding plate, the holding plate is joined to a guide sleeve by means of said screws and spring elements are arranged between heads of said screws and the holding plate.
9. Apparatus according to claim 1, in which the components of the housing, which housing receives granules formed by the apparatus, can be moved vertically with respect to the cutting implement and the cutting plate.
10. Apparatus for granulating plastics melt and other materials substantially as hereinbefore described and illustrated with reference to the accompanying drawings.