NO132954B - - Google Patents

Description

The present invention relates to a closable container with

a rotationally symmetrical body with two end parts and a middle part, the end parts having a smaller radial dimension than the middle part and connected to the same by means of a transition zone in one piece with each end part and the middle part and with a cone shape.

The manufacture of containers of synthetic material, in particular of thermoplastic synthetic material, is well known. However, high costs and the lack of mechanical strength of the synthetic material have prevented the production of various types of large containers, so that the use of synthetic material was limited to the production of relatively small containers and/or of large containers where the mechanical strength does not play a significant role role, because said containers are at rest and/or carried by other constructive parts.

It is likewise known to produce containers with a content of a few dozen liters by winding filaments impregnated with synthetic resin around a core. Many systems are known for this purpose, but their use in practice has been hindered by the high production costs.

Large containers intended for transport, such as oil containers and the like, with a content of over 100 liters were manufactured and are still manufactured from sheet metal, with the exception of the containers for which the traditional wooden material is still used (so-called stave barrels), for example herring barrels, whiskey barrels and the like.

The purpose of the present invention is to provide a solution to the problem of manufacturing large containers suitable for transport, with relatively low weight and considerable strength.

In accordance with the invention, this task is solved by each transition zone comprising a prefabricated reinforcement ring of synthetic material glued or welded to said zone with an inner surface adapted to the cone-shaped zone.

The rings provide the necessary additional strength when moving the container, in the event of a fall and during transport. Due to the fact that the separately produced rings are profiled, and that they form a unit with the main part, considerable strength is achieved under all the loads that occur. The surprising feature is that containers according to the invention, when they are completely filled with a content of more than 100 litres, can be treated in a brutal way, as is the case during transport overseas to distant areas, without leakage or permanent deformations occurring . The construction of the metal containers is such that permanent deformations can occur. The container according to the invention is light in weight, inexpensive to manufacture and strong.

It should be noted that the body of the container can be made in any suitable manner. It should also be noted that the rings, which are produced separately, may have been produced, among other things, by means of injection molding or by extrusion. The rings can consist of a thermoplastic synthetic material, but it can also be produced from a thermosetting synthetic material. The connection of the rings to the main part, which has been produced by

welding or gluing, must be such that a unit is formed in the sense that the connection between the rings and the main part can withstand the loads that can occur in any direction. When the connection is made by melting the material in the main part and the ring, it is necessary to avoid internal material stresses, that the exit temperatures of the main part and the ring are equal, at least

practically identical to each other, as is usual in welding operations.

In order to solve the problem underlying the invention, experiments have been carried out with large containers made of thermoplastic synthetic material, where attempts have been made to increase the mechanical strength by supplying these containers with reinforcing tape, e.g. made of metal. It turned out for rotationally symmetrical containers of thermoplastic synthetic material that these metal bands were capable of absorbing the external radial loads. Due to the fact that the connection of the metal with the synthetic material was insufficient, the containers had only moderate strength against axial loads, as well as against inwardly directed radial loads, and impact. the firmness was also not satisfactory.

Experiments were also carried out with rotationally symmetrical containers made of thermoplastic synthetic material and reinforcing rings of the same thermoplastic synthetic material were attached to the containers during manufacture by shrinking them. However, internal material stresses occurred in the synthetic material, which were disadvantageous for the strength, especially for the impact resistance of the container. These stresses are the result of differences in material creep for the ring and the main part.

By using the same material according to the invention for both the container and the reinforcement rings, a very good connection can be achieved without internal stresses. Due to their construction, the reinforcing rings have sufficient mechanical strength in the radial direction to absorb stresses or

loads* By means of the reinforcement rings' fixed connection with the container, as these reinforcement rings are produced in a separate production, the axial strength of the container is increased, especially because the areas of the container that can be dented are made smaller, so that the influence of the reinforcement rings is noticeable over a large part of the container wall.

To avoid cracks in the main part of the container as a result of stress concentrations in the transition zones between the main part and the reinforcement rings, the main part of the container is provided on both sides and almost every reinforcement ring with channel-shaped grooves.

The main part of the container is preferably assembled from parts with different diameters, and the reinforcement rings are arranged in the area of the transition zones between these parts.

As a result, the placing in position of the reinforcement rings is made easier and can also take place more accurately. Moreover, the diameters of the parts that form the main part can be smaller when the parts are located closer to an end face of the béhblder.

The main part or the main part's components are preferably barrel-shaped. As is commonly known, the barrel shape is particularly advantageous in terms of strength1 due to the three-dimensional arc of the main body's shape. - ' ±" ■■ ..

The reinforcement rings are preferably mainly l-shaped in cross-section. A cross-section of this kind offers considerable rigidity, and it is also achieved that the container can be handled more easily, because it can be gripped with the help of the I-shaped cross-sections.

With the help of the invention, a container has been obtained which can replace both the usual metal containers for oil, paint, chemicals, fuel, etc. d<g>" the usual wooden herring barrels. The lid is then produced separately, f .e.g. by pressing or injection molding and has an edge that fits over an edge of the container wall where a gill band can be arranged. The lid can consist of another material.

Some embodiments of the invention shall be described in the following as pure examples with reference to the drawings, where fig. 1 is a side view, partially in section, of an embodiment of a container 1 according to the invention, and fig.' 2" is a one-sided view, partially in section, of another embodiment of a container in accordance with the invention. ~' " ' " ""' ' " ' -'

The drawing shows a container which is generally denoted by 1 and consists of a main part 2 and a bottom 3, which forms a. unit with the main part and a lid 4. The main part, 2 ..and^ the base 3 .is e.g. produced by blow molding.

In the embodiment shown, the main part consists of 2 ordinary

show three parts, a barrel-shaped central part .5 and two end parts 6 and 7/which become [gradv.is smaller towards the .outer ..ends. The transition zones both between the barrel-shaped middle part 5 and the upper end part 6 as well as between the barrel-shaped middle part 5 and the lower end part 7 are formed by conical parts 8 and 9.

In height with . the..'conic -parts ,8 and 9 .and around retain-

reinforcing rings 10 and 11 are arranged, and these are attached by means of xptation friction welding. These ring 10 and 11

is made using injection molding and has an L-shaped cross-section, with the shape of one flange adapted to the contour of the container at the height of the conical parts 8 and 9.

Rings 10 and 11 have a threefold effect. Firstly, they increase the container's radial strength both inwards and outwards. Secondly, they also offer axial strength, because they increase the container's resistance to dents. It must be noted that in this context the strength of the main part around the rings is close to the strength of the rings, so that even when stacking the containers on the main part, under which the rings of two containers placed on top of each other will lie closest to each other, the said containers will be deformed to a lesser extent. In addition, the upper ring 10 also stiffens the opening of the container, so that after filling the container • the round shape of the edge is maintained, on which the lid must close.

Thirdly, the holding properties of the containers are improved, not only because the rings form simultaneous installation lines, but also because these have. such a profile that the containers can be easily grasped.. For this purpose, the main part of the rings can be provided with suitable openings if necessary.

The strength of the container in both axial and radial directions is mainly achieved due to the good connections between the main part and the reinforcing rings. As a result, the container is divided into a number of areas with smaller surfaces, which largely divert their strength from the reinforcement ring.

In the one in fig. 2, the main part of the container is provided with four channel-shaped grooves 12 which extend on both sides and closest to the conical parts 8 and 9, on which the reinforcement rings 10 and 11 are to be arranged. In this way, cracks can be avoided in the main part immediately near the reinforcement rings as a result of stress concentrations L in the transition zones between the rings 10, 11 and the main part.

It will be clear that the invention is not limited

to the shown and described embodiment. It is thus possible, e.g. to give the reinforcement rings an anaei profile, they can e.g. be U-shaped, while it is also possible that the container can be of a different type consisting of two closed-adt-outer ends and one or more filling openings. Furthermore, it is now necessary to divide the main part of the container not into three parts, but into a large number of parts, in which case the number of reinforcement rings will increase accordingly.

Claims (3)

1. Closable container with a rotationally symmetrical body (2) with two end parts (6, 7) and a smaller part (5), Whereas the end parts (6, 7) have a smaller radial dimension than the middle part (5) and are connected by same by means of a transition zone (8, 9) in one piece with each end part (6, 7) and the smaller part (5), and with a cone shape, characterized in that each transition zone (8, 9) comprises a prefabricated reinforcement ring (10 , 11) of synthetic material glued or welded to said zone with an inner surface adapted to the cone-shaped zone. 2. Container according to claim 1, characterized in that the reinforcement ring (10, 11) is bound to the body with its boundary surface by means of channel-shaped grooves (12) formed in the body. 3. Container according to claim 1 or 2, characterized in that the cross-section of the ring is mainly l-shaped.