NO782504L - STORAGE CONTAINER OF PLASTIC FOR LIQUIDS, ESPECIALLY FUEL OIL CONTAINER - Google Patents

Description

Storage container made of plastic and determined

for liquids, especially filling

This invention relates to a plastic storage container

and intended for liquids, especially fuel oil, and. produced by blow molding and which have indentations in opposite side walls, the bottoms of which are welded together.

Heating containers made of plastic, which are produced by blow molding, have been known for many years. For the most part, several such containers are put together to form a so-called battery tank and generally have a cuboid shape with side walls with relatively large surfaces that tend to bulge out as a result of the static pressure of the liquid filling. In order to keep this bulge within limits, various precautions have been proposed with a view to stiffening the side walls. The previous and also today common precautions

for this purpose consists in arranging bandages which in the area of the side walls consist of flexurally rigid profiles. Such bandages are, however, relatively expensive, which is why other stiffening means have been tried.

Thus it has already been proposed (see DT-OS

25 22 094) to arrange internal ribs formed by the container wall

material. Another proposal (see DT-AS 21 15 507) consists in arranging large press-fits which are welded together in the middle plane of the container in opposite side walls of the container. Thereby, the container should take the shape of ..a. torus. To achieve this

the indentations must be made very large, so that the intake volume at given outer dimensions is significantly reduced compared to containers without indentations.

The purpose of the invention is to provide a container of the type mentioned at the outset in such a way that the indentations can be made relatively small. Another purpose of the invention is to provide a good stiffening of containers in the form of a square without bandages. According to the invention, this is achieved by the indentations having the shape of a truncated pyramid, the edges of which, seen in the side view of the container, are located below the horizontally extending pyramidal axis and up to the end walls which stand across the side walls, have such a position that the projection on the sidewall plane of the imaginary extensions of the pyramidal edges projecting from the sidewalls, they intersect the lower edges of the sidewalls near the ends of these lower edges.

The truncated pyramids protrude into the interior of the container, so that from the outside you can, so to speak, look into the interior of the myramid. are welded together, run obliquely to the horizontal plane.. These edges make up areas of particularly high rigidity and run in the direction of the container's most exposed places. These locations are located near the bottom of the container and near the lower edges of the container. . At the bottom of the container, the static pressure of the stored liquid is greatest. The danger of bulges is therefore particularly great near the bottom. With the special design of the press-in hinges, the most exposed parts of the container wall are, so to speak, bottomed out as a result of particularly stiff areas, where the overlapping press-in hinges are welded together: This makes it possible to achieve a significant improvement in the strength of the container, so that without having to use stiffening bandages and/or ribs, a sufficient stiffness is still achieved at an average egg thickness.

A location of the pyramid edges as specified in claim 2 is particularly advantageous, as the risk of bulging is particularly great at a certain distance from the corners of the container.

The pyramid edges that extend over the pyramid axis and

at an angle, can also serve to stiffen the container, as stated in claim 3.

The truncated pyramids can have different geometric shapes, provided they meet the basic conditions stated in the main requirement. Particularly suitable are shapes as specified in claims 4 and 5, which shapes are particularly suitable for largely square or rectangular side walls such as . the case in general is, as certain containers with such a shape can be put together in a particularly favorable way to form container batteries.

The axes of the truncated pyramids lie accordingly

claim 6 preferably below the center of the container. This rule of thumb is usually the most favorable because the static pressure of the liquid in the lower area of the container is greater than in the upper area.

This applies in particular to the most common cases where

in the container there is no negative pressure.

In the case of symmetrical, truncated pyramids, a position of the pyramid axis below the middle of the height is achieved when the (materially not present) pyramid base surface is not symmetrical to the middle of the height, but shifted somewhat downwards in relation to this height. If the base is arranged symmetrically to the center of the height of the container, the pyramid axis may also lie lower than the center of the height, in which case the truncated pyramid is skewed. Such designs are also within the scope of the invention.

In a side wall there can be several recesses. When the conditions are as stated in claim 7, generally only one pressing is used, while for longer containers such as, for example, stated in claim 8, several are arranged, e.g. two recesses in each side wall. The conditions according to the main requirement thus also apply to containers with more than one compression.

The invention is generally particularly advantageous in connection with cuboid containers (claim 9). The invention is particularly suitable in connection with containers with a recording

volume of 1000 to 2000 liters (requirement 10). However, this provision is not to be considered restrictive. Whether press-in is used will also depend on the wall thickness of the container.

The invention shall be explained in more detail under reference

to the drawings, if fig. 1 shows a storage container which has a press-in in both side walls, fig. 2 shows a section along the line II - II in fig. 1, fig. 3 shows, seen from the side, a storage container in which there are two press-in fittings in each side wall, and fig. 4 shows a section along the line IV - IV

on fig. 3.

The container according to fig. 1 ag 2 has a length L, a

height H and a width B. The ratio L/H is here approx. 1. The width is preferably chosen so that the container can be transported

through doorways, and a suitable measurement for B is 720 mm.

The container has a bottom 1, side walls 2, 3, end walls 4, 5 and a roof 6 and is shaped by the blue eye method. As is known, blow mold parts are produced in such a way that a plastic hose, more specifically polyethylene, is arranged between the mutually separated halves of a blow mold, and extruded in such a way that when the blow mold is closed, the hose is pinched from above and below, after which the hose, still in a plastic state, is inflated , so that the wall of the hose rests against the inner wall of the blow mould. In general, the hose wall underneath will be somewhat stretched.

The container's roof 6 is designed with connectors 17, 18 and 19, one for connecting a . filling line, one for connecting a drain line and one for connecting one air line.

A press-in is arranged in each side wall 2 and 3

7 respectively 8. These are formed using protrusions in the opposite walls of the blow mould. The end surfaces of the projections are then brought close to each other another is that the still plastic wall areas of the plastic hose are pressed together at 9 and thus welded together. The bottoms of the recesses 7a and 8a are thus formed by both sides of a wall 9.

According to the invention, the pressings 7 and 8 have the form of truncated cones, the base surface of which is not materially present. The edge of the imaginary base surface is formed by the edges 10 of each press-in, which in the embodiment shown have a right-angled shape with the sides 10a to 10d. The long rectangle sides 10a and 10c extend vertically, while the short sides 10b and 10d extend horizontally. The corners, where the side edges are connected to each other, are designed with roundings 10e with a relatively large radius. The other end of the pressing, Elate 7a (or 8a) is materially present. From the sides 10a to 10d of the base surface, the pyramidal walls 7b to 7e extend to the end surface 7a. l/eggs 7b to 7e butt together at the edges lia to lid. It is admittedly not a matter of sharp edges here, but of edges formed by rounding with a relatively large radius.

The truncated pyramids are symmetrical to a pyramidal axis 12 which extends horizontally and through the bases 7a and 8a in the middle of these. The distance a of the pyramid axis 12 from the base is essentially less than the center au; container height, as shown

by the dash-dotted line 13 in fig. 2.

The pyramidal edges 11a and 11b are so oriented that the projection of their imaginary extensions, as indicated by the dash-dotted lines 11a and 11b, intersects their lower edges. assigned side walls at points 15 and 15 which are slightly offset in relation to the container's lower corners. Those in fig. 1 indicated dash-dotted lines 11'a and 11', p are projections of the imaginary extensions of the pyramid edges 11a and 11b on the main plane of the container wall 2. In reality, the lines 111a and 11'b project from the container wall.

With the aid of the pyramid edges 11a and 11b, particularly rigid areas are achieved in the 2 lower parts of the side wall, i.e. the side wall in the area of the lines 11'a and 11'b, so that the side wall here

si is bound with the help of the wall part 9. Since there is an exact and equal truncated cone in the side wall 3 lying above, symmetrical conditions are achieved with the help of the mutual bond between the truncated pyramids. The pyramid edges 11a and 11b can be regarded as a kind of tensile band that reinforces the exposed area in the lower part of the side walls.

Imaginary extensions of the pyramid edges lic and Ild are likewise indicated by dash-dotted lines and denoted by ll'c and 11' d. The projection of these lines intersects the side wall's 2

upper edge at points 20 and 21, which points are less close to the upper corners of the container than points 15 and 16 at the lower corners of the container. This is because the axis 12 is somewhat lower than the center 13 of the height of the container. A storage container for liquids, in particular a fuel oil tank, is generally used without excess pressure, so that only the static pressure of the liquid filling is effective. For this reason, it is appropriate to advance the axis 12 downwards in relation to the center of the container height.

If a container is under overpressure, the bracing by means of the pyramidal edges lic and lid also has a significant importance. In this case, it may be appropriate to arrange the pressings symmetrically to the height of the center 13.

While fig. 1 .and 2 show a container, in which the side walls are mostly square^ shows fig. 3 and 4 a container, the length of which is greater than the height. The ratio L'/H' is here significantly greater than 1, in the case shown approx. 1.2. In each side wall there are two recesses as shown in fig. 3 is denoted by 22 and 23. These compressions are. practically the same, as already described above, so that it would be unnecessary to repeat the detailed description. Fig. 3 also shows extensions of the pyramid edges, which extensions are denoted by 24 to 31. The intersection points between these side edge extensions and the edges of the side walls are denoted by 32 to 39. As can be seen from the drawing, points 32, 35, 36 and 39 are located in the side wall's corner areas,.

while the other points 33, 34, 37 and 38 are located in the middle area of the container. For even longer containers, additional pressings can be arranged. The invention thus brings with it that advantage

that containers can be manufactured with a large length. This is not immediately possible when using a casing ring or ribs, as the casings or ribs must absorb a very large bending moment when the container is very long.

Claims (10)

1. Storage container made of/plastic and intended for liquids, especially fuel oil, and produced by blow molding and which has indentations in opposite side walls (2, 3), whose bottoms (7a, 8a) are welded together, characterized in that the indentations (7, 8 ; 22, 23) generally has the shape of a truncated pyramid, whose edges (lia,. 11b), seen in the side view of the container, are located below the horizontally extending pyramid axis (12). and until the end walls (4, 5) which stand across the side walls (2, 3), have such a position that the projection on the side wall plane of the imaginary extensions (ll'a, 11'b, 24, 27) of the pyramid edges (lia, lib) projecting from the side walls (2, 3), they intersect the lower edges (14) of the side walls (2, 3) near the ends of these lower edges (14) (intersection points 15, 16; 32, 35). 2. Container according to claim 1, characterized in that the intersection points (15, 16; 32, 35) are located at a distance from the lower side wall edges (14), such as a distance of 10 - 20% of the entire edge length. 3. Container according to requirements. 1 or 2, characterized in that the edges of the truncated pyramids (lic, lid) which, seen in the side view of the container, lie above the pyramid axis (12) and in the vicinity of the end walls (4-, 5), has such a position that the projection on the side wall plane of the imaginary extensions (ll'c, lltd; 28, 31) projecting from the side walls (2, 3) essentially intersects the ends of the upper edges of the side walls (2, 3) (intersection points 20,21; 26, 39). 4. Container in contents. to one of the claims 1-3, characterized in that the truncated pyramids have essentially rectangular base surfaces with rounded corners (lOe) of the base surface, and that two of the sides (10b, (10d)) of the base surface run parallel to the side walls (2, 3) side edges (14) and top edges. 5; Container according to claim 4, characterized in that the long rectangle sides (10a, 10c) at rectangular base surfaces run vertically. 6. Container according to one or more of the preceding claims, characterized in that the axes of the truncated pyramids (•12) lie below the center (13) of the container. 7. Container according to ten. 3 one of the preceding claims, characterized in that containers, in which the ratio ..between length (L) and height (H) is essentially 1, have only one press-in (7, 8) in each. of the side walls (2, 3). 8. Container according to one of claims 1 - 6, characterized in that containers, in which the ratio between length (U) and height (H <1> ) is significantly greater than 1, e.g. 1.2 or greater, has more than one, preferably . two pressings (22, 23) in each side wall. 9. Container according to one of the preceding claims, characterized in that it is largely square-shaped. 10. Container according to one of the preceding requirements, characterized by the fact that it has a recording volume of approx. 1000 to approx. 2000 litres.