APPARATUS FOR THE MANUFACTURE OF A PLASTICS FILLING MATERIAL AND A METHOD OF USING THE APPARATUS

Abstract

Plastic sheet elements (19) having a size and deformation suitable for use as a filling material in pillows, duvets and the like are manufactured by feeding one or more plastic sheets to a shredding apparatus (6) which has a rotating drum (9). Loosely hanging knives (12) are mounted (11) near an outermost edge of the drum (9), and are pivoted outwards during rotation to thereby cut, deform and twist the sheet to form “curly” elements (19), which are sucked out through openings (14) in a screen (8) located below the drum (9). By adjusting the feeding of the sheet (4), the rotation of the drum (9) and the magnitude of the negative pressure, various sizes and configurations of cut individual sheet elements (19) are produced.

Description

BACKGROUND

The invention relates to an apparatus, and a method of using the apparatus, for the manufacture of a filling material in the form of plastics sheet elements of individual pieces of sheet for use as a filling in pillows, duvets and the like, the sheet elements being manufactured by separation of a web of sheet. The apparatus comprises a housing in which a drum roller is rotated, with loosely hanging knives mounted on the drum, a screen extending at a distance from the outermost path of the knives, through which screen the pieces of sheet are sucked out.

Filling material of this type, comprising small sheet elements of wavy shape, is very suited as a filling in bedclothes, etc., since the material forms a filling mass which is suitably soft and resilient, and which has suitable insulating properties.

This provides the advantage that duvets, pillows, etc. may be washed at relatively high temperatures, which ensures a good hygiene in contrast to feather filling from poultry, which does not tolerate relatively high temperatures.

Previously known fillings are preferably manufactured by cutting up a layer of sheet material and deforming this material between for instance two rollers.

An example of such a manufacture of plastics sheet elements is known from EP 0 476 012. The drawback of this method is that it is very slow, and that the manufacturing capacity is poor. To this should be added a relatively large consumption of energy, and the low possibilities of switching the method to the generation of elements having a variety of sizes and shapes.

An example of a method and a hammer mill for the recovery of plastics sheet with a view to chopping the sheet to small pieces which may be re-used after cleaning of dust and similar impurities, is known from JP 2003 001128 A.

This method and hammer mill solely serve to chop the sheet into smaller pieces which, however, are not suitable for use as a filling material. This is due partly to the relatively thick sheet material which is chopped, and partly to the structure of the hammer mill with relatively long knives, which chop the sheet by a combined beating and cutting action. Therefore, the material will be chopped into small pieces which lack the ability to keep a distance to adjacent sheet elements. Thus, softness and insulation will be lacking when this material is used as a filling in pillows and the like.

SUMMARY OF THE INVENTION

It is an object of the invention to remedy these deficiencies and drawbacks, and this is achieved according to the invention by the use of a shredding apparatus, where knives are mounted on a drum at a distance from an outermost edge of the drum, which essentially corresponds to a distance between the drum and a screen.

In this surprisingly simple manner, it is possible to manufacture a considerable amount of pieces of sheet having a heretofore unknown bent shape with a consequent resilient property, thereby providing partly a great manufacturing capacity, partly a good “filling capacity” because of the very wavy elements. To this should be added the relatively great mutual distance between the individual elements and thereby the high degree of elasticity and insulating capacity. In practice, this filling has been found to be more comfortable than previously known plastics sheet fillings, since it feels and functions very much like down from poultry.

Because of the relatively short knives, an “arbitrary” wave shape of the individual elements is achieved, since the knives will deform, twist and stretch the individual elements with a relatively small impact from various directions and at various distances and thereby at various impact angles.

When several layers are fed as sheet layers put together, a multiplication of the manufacturing capacity is achieved, and also a better possibility of dimensioning the individual elements, it thus being possible to adjust the size and the shape of the individual elements during the feeding.

When sheets of sizes down to 5 and 15 μm are fed, it is possible to provide elements having the same shape as down, that is, with frayed edges and curvatures ensuring the desired effect as a filling material corresponding to natural feathers.

Finally, it is expedient to be able to adjust both the speed of rotation of the drum and the magnitude of the negative pressure, as thereby, it is possible to adjust the size and the shape of the individual plastics elements.

BRIEF DESCRIPTION OF THE DRAWINGS

An example of an embodiment of the invention will be described more fully below with reference to the drawings, in which FIG. 1 shows a section through a system for the manufacture of sheet elements seen in the direction I-1 in FIG. 3;

FIG. 2 shows an enlarged section of part of a drum, a working gap and a screen;

FIG. 3 shows a section through the system seen in the direction III-III in FIG. 1; and,

FIG. 4 shows an enlarged sheet element according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

FIGS. 1-3 show an example of a system for the manufacture of a filling material in the form of sheet elements, a single one of which is shown in FIG. 4.

The sheet used is a generally known polyethylene (PE) sheet with a thickness of about 12-18 μm, preferably between 5 and 15 μm.

As shown in FIG. 1, basically, one or more rolled-up sheets may be used. Three arranged rolls (1, 2, 3) are shown in the drawing.

From there, a web of sheet 4 is rolled out, which is then either single-layered or multi-layered, and which is fed by feeding rollers 5 to a shredder system, which is incorporated in a housing 6 in the example shown.

A drum 9 is mounted in the housing, the drum being rotated on a shaft 10 by means of a motor (not shown).

The drum 9 is composed of circular discs 18, which are mounted on the shaft 10 with spaces between adjacent discs.

Bearing rods 11 are mounted near the circumference and extend in parallel with the shaft 10, but near the circumference of the discs. FIG. 1 shows three bearing rods 11, but there may be fewer or more.

A knife 12 is suspended in each space, each knife being able to swing out and in between the discs when the drum is rotated.

The individual knives 12 serve as cutting and beating elements corresponding to choppers in a hammer mill during the rotation of the drum 9.

The drum 9 has mounted therearound a guide plate or a shield 7 at the top, a plate for guiding the web of sheet 4 after the feeding plate which serves as a guide plate 17, while a screen 8 is mounted on the lower side of the drum, the screen being curved to create a gap 13, as shown in FIG. 2.

The screen 8 is a plate in which holes or openings 14 are provided. These holes 14 have such a size that sheet elements 19 will be formed when the knives 12 work the sheet 4 against the screen 8 and the openings 14.

As will appear from FIG. 2, the individual knives 12 are relatively short, and their suspension mount 11 is disposed at a distance from the outermost edge of the drum 9, which essentially corresponds to the distance between the drum 9 and the screen 8.

The actual working takes place in the gap 13 between the discs 18 of the drum and the screen 8, as will appear from FIG. 2. It is noted that the knives 12 do not touch the screen 8 during the movement.

Below the screen 8, vacuum is established in the space 15 by means of a pump 16. This vacuum draws the sheet elements 19 out through the openings 14 and moves them further out via channels, etc. in the direction of the arrow 17.

Then, filtering of small particles, dust, etc. from the finished sheet elements 19 may take place in a generally known manner.

The method will be described now.

The drum 9 is caused to rotate at a suitable speed, which may be varied according to the dimensions of the sheet elements. Then, the feeding rollers 5, the web of sheet 4 are moved into the space 13 between the screen 8 and the knives 12 in their extended position.

The knives 12 will then work the sheet, as they will partly cut the sheet into small pieces, partly pull and twist these pieces to form a “curly” sheet element 19, as indicated in FIG. 4.

The dimensions of a single element 19 may be about 10-20 mm on each side. Following this working, the elements 19 are sucked out through the openings 14 in the screen 8 and further on for possible filtration and packaging.

The method provides a considerable degree of adjustability to achieve the specific properties of the filling material, since the speed of rotation of the drum 8, the negative pressure in the space 15 as well as the feeding speed of the sheet 4 may be adjusted to achieve the desired size and deformation i.e., “curling”, that is the desired shape of the individual finished elements 19.

Claims

1. A shredding apparatus for the manufacture of a filling material in the form of plastics sheet elements comprised of individual shredded pieces of plastic sheet, the plastic sheet elements being of a size and deformation suitable for use as a filling in pillows, duvets and the like, said shredding apparatus comprising: a housing;a drum disposed in the housing and being rotated therein;feed rollers for feeding a web of sheet material to the drum;loosely hanging knives mounted on the drum, said sheet elements being manufactured by said knives cutting into the web of plastic sheet fed to the drum roller; and,a screen extending at a distance from an outermost path of the knives, pieces of sheet being sucked out through openings in the screen via a negative pressure being applied thereto;wherein the loosely hanging knives (12) are mounted (11) on the drum (9) at a distance from an outermost edge which essentially corresponds to a distance (13) between the drum (9) and the screen (8).

2. The shredding apparatus of claim 1 wherein a speed of rotation of the drum and a magnitude of the negative pressure are adjusted for adjusting a size and amount of deformation of individual plastic sheet elements.

3. The shredding apparatus of claim 1 wherein the drum (9) is composed of adjacent circular discs (18), mounted on a shaft (10), with spaces between the adjacent circular discs.

4. The shredding apparatus of claim 3 wherein at least one knife (12) is suspended in each space, each knife being able to swing out and in between the discs when the drum is rotated.

5. A method for manufacturing a filling material in the form of plastics sheet elements comprised of individual shredded pieces of plastic sheet, the plastic sheet elements being of a size and deformation suitable for use as a filling in pillows, duvets and the like, said method comprising: providing a shredding apparatus having a housing, a drum disposed in the housing and being rotated therein, feed rollers for feeding a web of sheet material to the drum, loosely hanging knives mounted on the drum, for cutting into the web of sheet fed to the drum, and a screen extending at a distance from an outermost path of the knives, pieces of sheet being sucked out through openings in the screen, the loosely hanging knives being mounted on the drum at a distance from an outermost edge of the drum which essentially corresponds to a distance between the drum and the screen;feeding the web of plastic sheets to the shredding apparatus (6), said knives cutting the plastic sheet for forming shredded plastic elements, and,applying a negative pressure to the screen for drawing shredded plastic elements through openings in the screen; and,collecting the plastic sheet elements.

6. The method according to claim 5, wherein a plastic sheet has a thickness of between 5 and 15 μm.

7. The method according to claim 5, further comprising adjusting a speed of rotation of the drum and a magnitude of the negative pressure to adjust a size and amount of deformation of individual plastic sheet elements.

8. The method according to claim 6, further comprising adjusting a speed of rotation of the drum and a magnitude of the negative pressure to adjust a size and amount of deformation of individual plastic sheet elements.