NO881283L - FLEXIBLE CONTAINER. - Google Patents

Description

The invention relates to a flexible container made of plastic or elastomer material, for the transport and storage of piece goods, for example vehicles or defense equipment, gases, liquids, ammunition or explosives, and provided with filling and emptying openings.

The invention also relates to a flexible container which is located in a kind of pit, as well as a container with a container or containers arranged therein.

It is known, for example, to transport liquids in a container, as for this purpose the container is supplied with a tightly closable inner container made of flexible plastic material. When filled, this container will essentially take the same shape as the interior of the container. In order to prevent the liquid in the container from being exposed to unwanted movements (wobbling or sloshing) during transport, nets or belts are fixed over the container in such a way that these will be decisive for the plastic container with regard to its upper extent and its movement possibilities.

Due to the size of the usual containers (the end surfaces have dimensions in the range of a few meters, while the length is about 10 m) the production of containers suitable for liquids presents problems, even when they have a shape in accordance with the block shape of a container hair. In addition, the plastic container during transport will be exposed to considerable stress as a result of the liquid's movements. For example, you can think of a container that is transported on a freight wagon. Such a freight wagon rolls on a grading slope and/or is exposed to other shocks, and runs, among other things, relatively undamped towards a stop. In such cases, the liquid can be the source of such great mass forces that the plastic container and the container are destroyed.

The problem underlying the invention is to be able to provide liquid containers that are suitable for use in containers, and furthermore it is a special purpose to also find such a container design that transport stresses will not give rise to destruction of the plastic container and the metal containers.

This is achieved with a flexible container as stated in the patent claims.

The container according to the invention is made of a suitable material. The material can be a multi-layered material, and the container appears by joining elongated webs together to form a hose. This production is technically solved, and you can bring sufficiently long webs together and, for example, with the help of high-frequency welding, build up a hose consisting of webs of polar plastic material.

The two opening ends of such a hose are then connected to each other by means of two mutually matching clamp connection parts. If you choose a hose that fills the largest possible part of the inner space in a container, then in the case of a straight line connection between the opening edges, a clamping connection part that is longer than the container is wide will be necessary. Therefore, according to one embodiment of the invention, the two clamping parts are made with clamping jaws which have a wave-shaped surface. If you use, for example, rack-like clamping jaws with a tooth angle of 60°, then by laying the edge of the hose over the wavy surface of the clamping jaw, you can use a clamping strip that has a length that is only 1/4 of the hose's circumference. With a suitable design, according to the invention, a length is chosen such that the clamping connection parts at both ends fit into the container's door openings, or are somewhat shorter. After the hose-shaped container is closed at both ends in this way, the clamping connection parts are fixed by means of spreading parts or the like at a certain height above the container's bottom surface, in the container's door frame. This attachment above the bottom surface of the container means that, firstly, the filled container will always have a specific shape determined by the container's preload, so that fluctuations can thereby be counteracted during transport and the container is not destroyed. In addition, suitable fastenings mean that the lower half of the blow-shaped container is also held in a tensioned position so that a complete emptying of the hose-shaped container is made possible.

The snake-shaped container according to the invention does not necessarily have to consist of two mutually equal upper and lower halves. On the contrary, it can be advantageous with an "asymmetric" design, because by designing the lower container part as a kind of vessel and by designing the upper container part as a tensioned membrane, a container can be produced which, after filling with the liquid that is to be transported, will almost certainly not be exposed to swinging stresses during transport.

The container according to the invention does not necessarily have to consist of a single snake-shaped casing. On the contrary, with a design with several enclosures, it is possible to achieve that dangerous goods can be transported or stored using a flexible container according to the invention. In this connection, a relatively thick-walled outer casing will mainly absorb the mechanical stresses, while a relatively thin inner casing in the form of a bladder or balloon serves for particularly tight storage of aggressive or dangerous media. For example, the inner layer can be formed by a balloon produced by blow molding of a material that is suitable for transporting the intended dangerous liquid. This inner balloon only needs to have a small mechanical firmness, because the outer casing will give the container the necessary firmness for absorption and transport of the liquid. Therefore, a material can be used for the outer casing which above all has the desired mechanical properties, without having to take into account the aggressiveness of the medium to be transported in the container.

In the event of damage to the outer part of such a flexible container according to the invention, this can be used again, when a closed balloon is introduced into the inner space.

It will also be possible to provide the snake-shaped container with a base in connection with the joining of the edge openings. This substrate, together with the two joined opening halves, is inserted between the clamp trays and fixed there. In this way, the container can be given an even greater mechanical loadability or firmness. It can also be achieved that precisely the part of the snake-shaped container that is particularly exposed to the bottom or the substrate is protected, especially when the container according to the invention is to be placed in a pit.

The invention will be explained in more detail with reference to the drawings, where: Fig. 1 shows a perspective view of a flexible container in a transport container made of metal

(container),

fig. 2 and 3 show longitudinal sections through a non-filled flexible

container,

fig. 4 and 5 the clamping parts in elevation and section,

fig. 6 shows a section through a clamping part according to fig. 5, fig. 7 shows an end part of a clamp part with a clamping direction, and

Fig. 8 shows a perspective view of the container

attached belt.

In the drawings, the outline of a container 10 is shown with dotted lines. A snake-shaped flexible container 11 is placed in the container 10, which along the side surfaces of the container has assumed a laterally flattened shape. The container II, however, otherwise has a mainly cylindrical hose shape.

The two mutually opposite openings in the hose are closed tightly by means of rectilinear clamp connection parts 14.

In fig. 1 above shows a filling option using a hose or an opening 12.

On the snake-shaped container 11, several attachment parts are placed along its length, here in the form of belts 13 whose respective free ends are attached to the lower area of the container 10.

Fig. 2 and 3 show the container 11 in an empty state in the container 10. In the embodiment in fig. 2, the filling and withdrawal device 12 is located above, while the embodiment in fig. 3 has a lower outlet nozzle 15.

From fig. 1-3, it appears that the fastening parts 14 are attached to the opening frame of the container 10, at a height above the bottom surface. It can be seen that thereby the container 11, even when filled with liquid, will have a shape that is favorable with respect to the oscillating stresses to which it may be exposed.

Figures 4 and 5 show a clamping connection part 14. This consists of two oblong, mutually matching clamping jaws 20 and 21. However, the mutually interacting clamping jaw surfaces are not flat, but have a matching wave shape. The two clamping jaws 20 and 21 occupy between them, as can be seen from fig. 5, the upper and lower edge parts of a snake-shaped container 12. If you tighten the screw connections marked 22, the two mutually opposite inner surfaces of the snake-shaped container 11 will be pressed against each other in a gas- and liquid-tight manner.

Fig. 6 shows the conditions on a natural scale, as on the right one can imagine the snake-shaped container 11. From this point the container changes to the essentially cylindrical shape shown in fig.l. The opening end of the container 11 can be seen on the left, in the compression area between the two clamping jaws 20 and 21. You will realize that instead of the two in fig. 6 shown edges belonging to a single snake-shaped container 11, several nested containers can also be clamped between the clamping jaws 20 and 21 in the same way.

In fig. 4, and also in fig. 6 and 7 show clamping parts 33. This concerns a bolt-like part 32 which is provided with a hexagon head in its outer area. The threaded portion of the bolt 32 is screwed into a suitable nut piece 31. The nut piece 21 is attached to the clamp connection part 14 at both ends of this. Especially of fig. 4 and 7, it appears that by turning the bolt 32, the total length of the clamping connection part 14 can be increased or decreased. After the snake-shaped container 11 has been closed tightly by pressing the two clamping trays 20 and 21 together, the clamping parts 14 are inserted into the container's 10 door opening. The bolts 32 are then unscrewed so that the clamp connection parts are fastened in the container's door frame, see fig. 1-3.

From fig. 8 it appears that bands or belts 13 are attached to the snake-shaped container II. A plastic part 44 is welded to the container 11 to form a loop, and in the loop there is a ring 45. The belt 13 is attached to this ring . The belt has a hook 46 at its other end. The belts 13 can be lengthwise adjustable and they are fixed in the lower area of the container 10 so that the snake-shaped container 11 is fixed with regard to possible transport fluctuations for the liquid.

Relevant materials for the tube-shaped container are plastic or elastomers. These can have one or more tissue layers. For example, elastomers (nitrile, butyl rubber and the like) and also thermoplastics (PVC, PP, PE) can be used. If materials with a polar character are used, the individual tracks can be welded together using high-frequency welding.

Instead of the clamping tray profile shown in Fig. 4 and 5, other labyrinth-like sealing options can be used. In this context, it is essential that one wants to place the largest possible snake-shaped container 11 inside a container 11, as in this connection the rectilinear clamp connection parts should not be larger than the cross-dimensional dimension of the container's door opening.

Claims (8)

1. Flexible container of plastic or elastomer material, for receiving piece goods, preferably liquids, or bulk goods, as the container is provided with filling and outlet openings and can be closed using clamp connection parts (14), characterized in that the container (11) is designed as a hose , that clamp connection parts (14) are only placed at the two hose ends, and that the clamp connection parts at at least one hose end are provided with a clamp part (31,32,33) for clamp fastening between the door posts of a container (10) or a stand, with a distance to the horizontal base of the container (10) or the stand. 2. Container according to claim 1, characterized in that the clamp connection parts (14) are made with extendable, swing-out or fold-out clamping parts (31,32,33) which can be attached to the inner edge of the door opening in the container (10) or the stand with clamping engagement. 3. Container according to one of claims 1 or 2, characterized in that the clamping connection parts (14) are arranged horizontally in the area of the snake-shaped casing (11) theoretical longitudinal symmetry plane. 4. Container according to one of claims 1-3, characterized in that the hose (11) is designed asymmetrically and consists of two parts arranged one above the other, the upper surface being smaller than the lower. 5 . Container according to one of claims 1-4, characterized in that the snake-shaped container (11) is formed of two or more layers or includes one or more enclosures, which are preferably not connected to each other or to the outer container, but are joined together and closed with the same clamping connection parts (14). 6. Container according to one of claims 1-5, characterized in that the outer snake-shaped casing is formed from interconnected, glued or welded webs, and that the inner casing is produced by blow molding. 7. Container According to one of claims 1-6, characterized in that the outer snake-shaped sheath has a thickness of 1 or up to a few millimeters, while the inner sheath has a thickness of less than one millimeter and is, for example, formed from a polyethylene foil or a polytetrafluoroethylene foil. 8. Container according to one of claims 1-7, characterized in that outer belt buckles (44) with belts (13) and hooks (46) are arranged on the outside of the snake-shaped container for attaching the container to the bottom of the container (10), to a foundation of the warehouse or to a carrier rack.