CH639040A5 - THIN-WALLED CONTAINER PRODUCED BY THE BLOW-MOLDING PROCESS. - Google Patents

Description

The invention relates to a container according to the preamble of claim 1.

Such containers are used in particular for holding liquids, mainly because of their low weight, the simplicity of their manufacture, their good appearance, the low production costs etc. As a result of the blow molding process, the wall thickness of the peripheral body of the container is inevitably quite thin.

Therefore e.g. for containers made of polyethylene terephthalate, which is known for its resistance to contents, chemicals and acids, because of its mechanical properties and various other properties, the production takes place under biaxial stretching. The latter is strongest in the circumferential body, so that it turns out to be relatively thin. This makes it particularly susceptible to internal pressure, external pressure, e.g. from above, as well as mechanical strength. All of this limits the areas of application of such containers, for a given blowing system, e.g. the maximum size or the filling weight, as well as transport security in the event of vibrations and the like.

In particular, external forces acting on the circumferential body tend to act concentrically on its central section measured in the vertical direction in order to deform it, e.g. bulge and in extreme cases burst. So if a constant external force acts on the entire circumferential body, it concentrically acts in a specific manner on a limited section, even if the circumferential body has sufficient durability. This leads to difficulties and disadvantages such as deformation and even damage.

Up to now, the lower mechanical strength of the peripheral body section has been compensated for by increasing the wall thickness to such an extent that the peripheral body can withstand the external force acting on it. This theoretically unnecessary additional consumption of synthetic resin material made the production of such containers extremely uneconomical. In addition, there is an unnecessary overpressure of the blowing fluid, e.g. the compressed air. Accordingly, the pressure resistance of the entire blow line system, the strength of all shape holding devices and the performance of the compressor must be increased. With biaxial stretching e.g. of polyethylene terephthalate, it is imperative to reheat the primary blank evenly after cooling in order to be able to carry out the aforementioned stretching. However, with an increased wall thickness, this requires a longer period of time, as a result of which the blowing system's output is reduced. A thickening of the wall therefore reduces the economy and the daily output and increases the material and investment costs and not least the weight of the container.

The object of the invention is to provide a container of the type mentioned in order to avoid the disadvantages of known designs and in particular to considerably increase the mechanical strength without increasing the wall thickness, the container for the human hand and its appearance in various ways to please. This object is achieved by the measures defined in the characterizing part of patent claim 1.

A particularly advantageous embodiment of the container is described in claim 2.

In the case of such a container, the load-bearing capacity in the central region of the circumferential body has been increased in a constructive manner and in a targeted manner in relation to external forces concentrically acting on the circumferential body. The latter are distributed in this way and flow out of the most critical area in such a way that the mechanical strength of the entire circumferential body is considerably increased.

A preferred embodiment of the subject matter of the invention is described in more detail below with reference to the drawing, in which:

25 Figure 1 is a container in side view. and

Fig. 2 on a larger scale the section II of Fig. 1 in section.

The container 1 has a completely biaxially stretched circumferential body 2 with a constriction 3, which is set back in a curved manner in the central region over the entire circumference of the circumferential body 2 or the jacket. The constriction 3 resembles a circumferential groove, the sole area of which, i.e. Bottom part, opposite a circumferential projection 4 protrudes curved outwards. Through the circumferential projection 4, the constriction or circumferential groove 3 has a profile which corresponds to the letter W with smoothly rounded corners and transition points. The height of the peripheral projection 4 is smaller than the depth of the constriction 3.

40 If the container 1 is filled with liquid, the relatively deep constriction 3, which is formed in a substantially central region of the peripheral body 2 measured in the height direction of the peripheral body 2, serves, i.e. between the upper and lower ends thereof, to relieve an internal pressure concentrically acting on said area into upper and lower sections along both inclined side walls. In this way, the internal pressure does not act concentrically on the central section in the height direction of the peripheral body 2 but is distributed 50 over the wide area of the peripheral body 2. In this way, the internal pressure per unit area acting on the peripheral body 2 is somewhat greater than in the absence of the constriction 3 , but the internal pressure per unit area acting on the latter is much smaller than in the absence of the constriction 3.

In other words, because of the constriction 3, the internal pressure should act substantially uniformly on the entire area of the circumferential body 2. Accordingly, it is no longer necessary at all to increase the wall thickness of the entire circumferential body 2 in order to increase the strength of a limited section of the circumferential body 2. The entire body of the peripheral body 2 can therefore have the small wall thickness which can withstand the above-mentioned substantially uniform internal pressure 65.

In this way, it is also achieved in terms of construction that the constriction 3, which is formed in an inwardly curved manner, is easily subjected to an elastic deformation,

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since a prestressing force acts on the container 1 in the axial direction. The latter causes a simple elastic deformation of the constriction 3 in order to absorb and counteract the pretensioning force before a deformation dangerous for the peripheral body 2 occurs. The ability of the constriction 3 to counteract the prestressing force by elastic deformation is of course limited. Therefore, if the biasing force is gradually increased, and thereby the degree of elastic deformation of the constriction 3, the deformation is finally concentrated at the bottom of the constriction 3 until the latter bulges and breaks. Therefore, the circumferential projection 4 is molded in there in order to increase the resistance of the constriction 3 against bulging.

The overall design reveals that the peripheral projection 4 has no particular influence on a certain degree of elastic deformation of the constriction 3, specifically because of the prestressing force along the axis of the container 1. However, as the degree of elastic deformation increases, the circumferential protrusion 4 deforms itself in one direction, so that the increase in the elastic deformation is hindered.

In other words, the elastic deformation of the constriction 3 as a whole increases to move the bottom of the constriction 3 inwards, while the deformation of the peripheral protrusion 4 itself increases in a direction that causes its bulging outward. As a result, the elastic deformation of the constriction 3 cannot be concentrated at the bottom of the circumferential projection 4, and the entire constriction 3 including the circumferential projection 4 is deformed substantially uniformly.

The entire constriction 3, including the circumferential projection 4, is therefore deformed essentially uniformly, namely elastically and in order to counteract the prestressing force acting in the longitudinal direction, without concentrating the elastic deformation on the specific section. The extraordinarily effective dent resistance is thereby achieved.

The strong internal pressure should act on the section of the provided circumferential projection 4, in comparison to the case in which the circumferential projection 4 is missing. However, since most of the internal pressures acting on the central portion in the height direction of the peripheral body 2, in which the constriction 3 is arranged, are diverted upwards and downwards through its inclined side walls, an increment of the internal pressure acting thereon is only very small.

In order to further increase the buckling resistance of the peripheral body 2 against the prestressing force acting in the longitudinal direction as a whole, it is advantageous to arrange a number of small peripheral recesses 5 on practically the entire area of the peripheral body 2 (FIG. 1). The latter are not influenced at all by the usual longitudinal biasing force, but only exert their effect to such an extent that they are able to prevent the container 1 from breaking depending on the magnitude of the biasing force if an excessive biasing force is exerted becomes.

The reason for this is as follows: in the state in which the portion of the recess 5 has to be subjected to the elastic deformation, it is time that the uniform elastic deformation of the constriction 3 as a whole, including the peripheral projection 4, has already reached its limit value, and the resistance to such a strong biasing force to continue the elastic deformation is not required at the stage of designing the container 1.

The increase in the buckling strength of the peripheral body 2 is accordingly a secondary purpose of the recesses 5. Their main purpose is the decorative effect, in order to give variety to the external appearance of the container 1 as a whole and to arouse full interest.

The new container design makes it possible to exert the external forces, such as the internal pressure of the container 1 and the pretensioning force exerted in the longitudinal direction, essentially uniformly and distributed over the entire circumferential body 2. Due to the effect of the external forces, elastic deformation easily occurs, but its local occurrence can be avoided. Such a container can therefore withstand these external forces extremely effectively, so that its mechanical strength is extraordinarily high. Since local concentrations of external forces and local deformations can be effectively avoided, the wall thickness of the peripheral body 2 can be made thinner than before, so that the material consumption is reduced for a given size and filling volume. In addition, there are improvements in the pressure resistance of the pressure fluid device, the heating speed, and the working speed that can be achieved in blow molding. This can significantly reduce manufacturing costs and significantly increase production speed and performance.

Finally, because of the spatial arrangement of the constriction 3, the improved grip of the container 1 should be mentioned. If, when gripping the container 1 with only one hand, fingers are in the constriction 3, the container 1 cannot slide out of the hand because it is securely held. A deep constriction opens up the possibility of securely gripping even thicker containers with one hand than was previously possible. The previously monotonous container of the type mentioned can now be given a more pleasing appearance in many ways by the constriction 3, so that the latter also has a decorative character. So far, the side wall 2 has only been corrugated, but this can also be done with the new container.

All this also applies to containers that have two or more constrictions 3. In this context, the essentially central section is to be understood here in the broadest sense, i.e. than the section between the top and bottom of the side wall. In the case of relatively high containers and / or specifically heavy liquids, the number, design and arrangement of the constrictions are appropriately selected taking into account the hydrostatic pressure in the full container. This opens up numerous new perspectives for the designer as well as for the designer of containers. In the case of rough treatment, as is often unavoidable with assembly line filling, transportation and goods handling, the advantages of the new container are particularly noticeable due to the decreasing reject rates. Of course, all other plastic materials suitable for blow molding, preferably biaxially stretchable, are also suitable for the container, but particularly preferred are those which contain polyethylene terephthalate.

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Claims (2)

639040 2 PATENT CLAIMS 1. Made by the blow molding process thin-walled container made of plastic material, with stretching in the casting direction, characterized in that a substantially central portion of a container circumferential body (2) measured in the vertical direction is pressed inwards and with a curvature on the circumference such that at least one constriction (3) is formed, and that a bottom part of the latter protrudes somewhat outwards and with a curvature on the circumference, and in this way forms a circumferential projection (4). 2. Container according to claim 1, characterized in that the plastic material is biaxially stretched and preferably contains polyethylene terephthalate.