EP1666377B1

EP1666377B1 - Flexible, double-layer container

Info

Publication number: EP1666377B1
Application number: EP06101459A
Authority: EP
Inventors: Gerd Theodor c/o Petra Brand Brand; Michael Hirschhäuser; Frank Dieter Hünig; Johannes Andreas Joze Middelman; Thomas Riedemann; Roland Schaffer; Hans-Joachim Seydel; Hans Jürgen Strempel
Original assignee: Evonik Degussa GmbH
Current assignee: Evonik Operations GmbH
Priority date: 2001-07-11
Filing date: 2002-07-09
Publication date: 2009-02-18
Anticipated expiration: 2022-07-09
Also published as: UA76169C2; PL207558B1; CA2452775C; PL367330A1; JP4088668B2; EP1666377A2; KR20040019054A; ATE345266T1; ATE423070T1; KR100599026B1; CA2452775A1; CA2569061A1; EP1404576B1; EP1666377A3; CA2569061C; ES2276943T3; EP1661612A1; EP1404576A1; WO2003006314A1; CN1248912C

Abstract

A flexible container (6) for the repeated filling and draining of finely divided solids, characterized in that it consists of at least two plies (7,8), wherein one ply is made of an air-permeable, supporting material (7) and the other ply (8) consists of a filter material.

Description

The present invention relates to a flexible container.
The handling of pourable finely divided solids having a high air content and extremely low pour density such as, for example, finely divided silica poses various problems. Producers as well as final consumers are faced with the fact that these materials raise dust even in the slightest air convection. The formation of dust must be avoided to protect the personnel dealing with the product from possible damage to their health by breathing in the dust. In addition, the low pour density increases transportation costs because the ratio of container weight to filling weight is high and a correspondingly large amount of packaging material is required.
Owing to its three-dimensional spatial branch structure, finely divided silica is a product having an extremely low compacted bulk density of about 40 to 50 g/l. Owing to its fine structure, finely divided silica is capable of binding a very large amount of gas, for example air, so the product is put into a quasi-fluid state of about 20 to 30 g/l.
Spontaneous escape of this removable air content takes place only very slowly and incompletely. The dust problem is also increased in this fluid state because the mobility of the finely divided silica is extremely high.
Pourable finely divided solids with a high air content and extremely low pour density are therefore introduced into air-permeable bags predominantly by means of an externally applied vacuum. The duration of filling increases as the air content increases.
The bags consist of three to four plies of paper, and one ply of the paper may additionally be laminated with polyethylene as a barrier against penetrating moisture. To achieve the desired air permeability during the filling process, all plies are microperforated. This has the effect that the product is compressed as it is introduced into the bag and its filling density increases relative to the natural pour density.
It is also possible to carry out preliminary deaeration using special press rollers, but this can always give rise to structural damage which may adversely affect the properties of the solids in use.
The higher proportion of the product in the container weight reduces transportation costs, but this saving is offset by additional expenditure for procuring the special container and the necessary filling devices.
A process and a receptacle for repeated filling with and emptying of pourable product having a low pouring density is known from EP-A-0 773 159 . The woven fabric receptacle described therein, the so-called big bag or also super bag, consists of flexible air-permeable woven fabric, preferably a single or multiple ply of plastic woven fabric with at least one inlet. This woven fabric receptacle is also filled using vacuum filling systems. A vacuum is applied to the woven fabric receptacle and the product is aspirated through the open inlet into the woven fabric receptacle until a predetermined filling weight is achieved. The issuing gas is distributed over the entire surface of the woven fabric receptacle. During the filling process, the product is reversibly compacted, as when being poured into bags, without its structure being destroyed in the process.
DE-A-198 39 106 describes flexible large containers for finely divided solids having a high air content for repeated filling using vacuum filling systems, which consist of at least two superimposed plies, an inner ply consisting of uncoated air-permeable woven fabric and an outer ply being dustproof and being coated with a moisture barrier and these plies being mutually connected by a special seam in such a way that the container may only be aerated through it.
With this design of containers, in particular the increase in moisture in the filling product during storage in the large container could be reduced.
As the air is no longer able to escape over the entire surface of the woven fabric receptacle, however, a drawback is that the period of time required to reach a predetermined pouring density is considerably extended and the filling capacity therefore reduced. To compensate for this, the DE-A-198 39 106 describes a particular process for filling this large container, with which the filling material is subjected to preliminary deaeration prior to filling and a further deaeration via the seams of the fabric is carried out during filling. The preliminary deaeration and therefore partial compaction of the filling product are also effected by the application of vacuum.
A drawback of the process described in DE-A-198 39 106 is the extremely high expenditure on apparatus as vacuum systems are required for both preliminary compaction and filling of the large container. Despite this expenditure, the filling capacity is still too low, so the process described in DE-A-198 39 106 is uneconomical overall.
It is accordingly an object of the present invention to provide a container to be filled in particular with finely divided solids having a high air content, with which a high filling capacity with adequate compression of the solids to be poured may be achieved with low expenditure on apparatus and therefore low capital outlay.
The subject of the invention is a flexible container for the repeated filling and draining of finely divided silica and to be used for amounts up to 1.200 kg having a high air content and extremely low pour density, which is characterized in that,
it consists of at least two plies, wherein one ply is made of an air permeable, supporting material PP woven ribbon material with a weight of 75 to 300 g/m³ and the other consists of filter material HDPE non woven "Tyvek" by DuPont, whereby the air permeable supporting material is arranged on the outside and filter material on the inside, and it permits a dust-free filling through compacting on the inside of the container, whereby clearly higher bulk weights can be a achieved,
whereby the highly air-permeably inner ply acts as a filter for the product and permits the air to escape, whereby the outer ply absorbs the forces, but permits the air to escape,
whereby the outer ply is hot coated so that air can pass through.
The container can be filled by an apparatus for filling containers, in particular with finely divided solids having a high air content, comprising a feed nozzle which may be introduced into the feed orifice of the container, wherein the feed nozzle is so designed that the solids may be introduced under pressure and the container is surrounded by a two-part or multi-part cage (3).
The filling of the container, in particular with finely divided solids having a high air content, is done by arranging the air-permeable container in an apparatus, air-tight connection of the container to the feed nozzle, filling of the container under pressure and removal of the filled container.
The subject matter of the invention is a flexible container for finely divided solids for the repeated filling and draining, characterized in that it consists of at least two ply, one above the other, wherein one play consists of an air-permeable supporting material that is preferably non-coated and the other ply consists of a filter material.
According to one embodiment of the invention, the air-permeable, supporting material can be arranged on the outside and filter material on the inside.
However, other combinations of the plies, from the inside toward the outside,are possible, wherein the combination of supporting and filtering element of the container is essential.
The container according to the invention can be designed for optional amounts of finely divided filler materials.
The container according to the invention can preferably be used for amounts up to 1,200 kg. In contrast, containers according to prior art could only accommodate filling amounts of 90 to 100 kg.
The material used for each ply can be commercially available material.
The container according to the invention permits a dust-free filling through compacting on the inside of the container, in particular using the apparatus according to the invention, wherein clearly higher bulk weights can be achieved.
The finely divided material can be drained from the container according to the invention through a preceding fluidization and simultaneous conveying.
For this, known drainage devices can be used.
The container according to the invention is shown schematically in Figure 3.
Optional combinations of the outer plies, the inner plies and the intermediate plies are possible, wherein the container has a supporting as well as filtering design.
This results in the following advantages as compared to the known technology:
The highly air-permeable inner ply acts as a filter for the product and permits the air to escape.
The outer ply and the intermediate ply(plies) absorb the forces, but permit the air to escape. As a result of this configuration, air is moved quickly through the walls and the product can be highly compacted inside the container with considerably higher filling weights than is possible with known systems (up to 1,200 kg as compared to the known 90-100 kg, depending on the product type).
Finely divided solids having a high air content may be poured with adequate compression of the solids in high capacities using the apparatus without high expenditure on apparatus. In particular, finely divided granular powdered solids having a high air content and selected from pyrogenic oxides, precipitated oxides, carbon blacks and modifications may be poured.
In particular with pneumatic conveyance of the filling product, the resultant pressure is sufficient to achieve appropriate filling of the container. The apparatus may have a special feed nozzle which is equipped with a flexible sealing skin and therefore allows dust-free pressure filling. The feed nozzle may be deformable and may therefore allow the filling of containers of various sizes.
The cage which is an important component of the apparatus has to withstand, in particular, the pressure required. At the same time, the cage gives the container adequate support during the filling process, to ensure that the container withstands the pressure applied and keeps its shape during the filling process.
Containers of a wide variety of shapes and of various materials may be filled in the apparatus. The materials may be: air-permeable plastic woven fabric, preferably polypropylene woven fabric, plastic woven fabric, textile woven fabric, cardboard, paper, paper plastic woven material, plastic non-woven fabric, textile non-woven fabric or composites of the aforementioned materials. The filling pressure is generally 0 to 8 bar, preferably 0 to 2 bar and particularly preferably 0.2 to 1.2 bar.
The containers according to the invention using the process may be of any conventional shapes and materials. For example, the containers may have a base area selected from a group consisting of polygon, circle, semicircle, ellipse, trapezium, triangle, rhombus, square and rectangle or a star-shaped base area. The containers may also have the shape of a hood, of assembled pockets or the shape of a tied-up bag. To ensure safe handling even during pressure filling, however, it is advantageous if, during the filling process, the cage contacts the container to be filled, as uniformly and snugly as possible. It is therefore expedient if the cage substantially corresponds to the shape of the container. Additional fittings in the cage allow adaptation to the respective container to be filled.
Owing to the excess pressure prevailing in the interior of the container, the air is carried off over the surface of the container. As the excess pressure is able to escape, compression of the filling product is also achieved. To enable the excess pressure to escape as rapidly as possible from the container, in particular in the case of a snugly fitting cage, it is expedient if the cage (3) itself is also gas-permeable. The cage may have walls with openings or with adequate porosity. This may be achieved, for example, by openings in the cage walls. It is particularly advantageous if the cage walls are produced from a material selected from perforated plate, mesh or netting, woven fabric or sintered material or a mesh material, because this allows high gas permeability with adequate stability to ensure that the container does not explode even under high filling pressures. The cage may be in several parts, preferably two parts. The cage (3) may have a bottom and may be designed without a bottom. Preferably, the cage (3) has no bottom.
The cage (3) may be in two or more parts and the apparatus comprises additional devices with which the two parts (3a, 3b) of the cage may be separated from one another and may be driven apart manually or automatically, preferably electro-pneumatically, to release the filled container. In particular in the case of cage shapes with a polygonal base area, it is expedient if the cage can be separated along a diagonal as this prevents damage to the container.
The cage may have no bottom, in other words the cage is open at the bottom. This embodiment allows particularly simple management of the filling process. After the two-part cage has been closed and the two parts have been connected to one another, the actual filling process can begin. For example, the container can then be positioned directly on a plate or a pallet, the feed nozzle can then be introduced into the feed orifice of the container and can be connected in an airtight manner to the container. On completion of the filling process, the two cage wedges can then be separated from one another and driven apart to release the filled container. As the filled container is then standing on a plate or pallet, it can easily be removed by a transportation device.
The present invention will now be described again with reference to figures.
Fig. 1 is a side view
Fig. 2 is a plan view of the embodiment according to Fig. 1 with opened cage.
As shown in the figures, the preferred embodiment comprises a framework 1 with two rails 2 at the top, along which the two halves 3a and 3b of the cage (3) may be moved by conventional drive devices.
In the embodiment shown in Fig. 1 and 2, the cage has a square base area and is divided along the diagonal into the two halves 3a and 3b. This ensures that the two halves can easily be separated from the filled container, even when the has been pressed against the cage owing to the high filling pressure.
The cage also has two half shells 4a and 4b which surround the feed nozzle (not shown) when closed.
As shown in Fig. 2, the cage 3 is open at the bottom and the container is positioned on a pallet or plate during the filling process. It is also advantageous, as shown in the figures, if the filling nozzle is arranged symmetrically with respect to the frame 1 so a cage half 3a may be removed further from the pallet or plate 5 to allow easy access, for example for a transportation device for removing the filled container.
Figure 3 shows schematically a representation of the container according to the invention.
On the one hand, the container 6 according to Figure 3 consists of two plies, namely the supporting, air-permeable outer material 7 (PP woven ribbon material with a weight of 75 to 300 g/m³).
The material is not coated so that air can pass through. This outer layer is supporting as well as carrying for product amounts up to 1,200 kg.
On the other hand, the second ply, the inner ply 8 (inliner) consists of a filter material (e.g. HDPE nonwoven "Tyvek" by DuPont, which holds back the finely divided product but permits the air escaping from the product to pass through (filter effect).
The drain 9 is shown schematically in Figure 4. The drain has a conical design and is thus particularly suitable for a special draining apparatus according to EP 0 761 566 B1 .

Claims

A flexible container (6) for the repeated filling and draining of finely divided silica and to be used for amounts up to 1.200 kg having a high air content and extremely low pour density,
consisting of at least two plies (7,8),- wherein one ply (7) is made of an air permeable, supporting material PP woven ribbon material with a weight of 75 to 300 g/m³ and the other (8) consists of filter material HDPE nonwoven "Tyvek" by DuPont, whereby the air permeable supporting material (7) is arranged on the outside and the filter material (8) on the inside, and permiting a dust-free filling through compacting on the inside of the container, whereby clearly higher bulk weights can be a achieved,
whereby the highly air-permeably inner ply acts as a filter for the product and permits the air to escape, whereby the outer ply absorbs the forces, but permits the air to escape,
whereby the outer ply (8) is hot coated so that air can pass through.