DE2009917B2 - Plastic container for filling goods under increased pressure, especially bottles - Google Patents

Description

The invention relates to a container made of plastic for filling material under increased pressure, in particular. Bottle with a body of circular cross-section and one smoothly merging into it closed bottom, in which the bottom has a central, outwardly convex polar cap-shaped Area, at least two hollow feet and between adjacent feet on one after has on the outside convexly arched dome-shaped envelope surface lying bottom intermediate areas, which are of the polar cap-shaped area and merge steadily into the fuselage wall, and in which the feet in a common level below the polar cap-shaped area and the intermediate floor areas Form horizontal standing surfaces, each standing surface from one to the top to the polar cap-shaped area ascending gusset-like inner partition, an outer one that continuously merges into the fuselage wall Boundary wall and two extending along approximately radially extending side areas of the standing area and diverging radially outward and extending to the respectively adjacent intermediate floor area extending and is limited in these transitioning side walls

ι υ A plastic bottle of this type is known from DE-Gm 19 41979 In this one-piece Manufactured bottle, the bottle base is essentially hemispherical or dome-shaped the dome-shaped surface are at least three feet distributed around the circumference of the floor formed by bulges that extend up to the level of the apex of the soil a The hemispherical Formation of the soil is with a view to the distribution of the result of an overpressure in the tensions that arise in a closed bottle are particularly favorable. The ones that limit the feet Side surfaces diverge outward in the radial direction, but run in the direction of the bottle axis essentially parallel to this. Those merging with their outer surface into the body wall of the bottle Feet must be designed to protrude relatively far in the axial direction so that the Stand area, which is formed by the feet, sufficiently far below the lowest point or of the poIu of the dome-shaped or hemispherical bottom is. This leads to the known bottle Significant difficulties in the formation of the bottom by blow molding, since here the normal stretching of the Plastic material is exceeded and discoloration as well as impermissible wall thickness reductions occur in the area of the feet. This problem is regardless of whether the bottle has only three feet or is formed with a larger number of feet, since in all these cases the feet from the hemispherical or dome-shaped bottom surface are formed protruding. Between neighboring Feet, the hemispherical or dome shape of the floor is retained over a large area, with the radial Circumferential expansion of these intermediate floor areas in the radial direction increases through this on a Intermediate areas of the floor lying on a spherical surface can reliably absorb bursting forces and stresses will. Apart from the difficulty of completely shaping the feet, these form

so the weakest part of the well-known bottle, as it esp. are sensitive and weakened to impact forces. It is known the curvature of the bottom of a to make such a bottle much flatter compared to the hemispherical shell shape, so that the Feet protrude only relatively slightly in the axial direction from this slightly curved floor surface must in order to form a common standing area under the curved floor area (see DE-Gbm 19 39 025). Here, too, the side surfaces of the feet diverge in the radial direction while their expansion in the axial direction takes place approximately parallel to the bottle axis. Here is the danger banned that the material is overstrained when the feet are formed. However, the burst strength is of the bottle bottom as well as the dimensional stability of this bottom is much lower than with the spherical or dome-shaped design of the bottom.

To overcome these difficulties and Use plastic bottles for liquids under pressure instead of glass bottles it is known that the plastic bottles are in two parts to train. Here the bottle itself is made in one piece formed and provided with a hemispherical bottom, which is particularly against the bursting forces is cheap In order to give the bottle the necessary stability, a separate base part, possibly made of a different material, attached This bottle is already on the market However, it has the disadvantage of high manufacturing and material costs due to the separate Production of a foot part and its attachment to the actual bottle are required. Since with mass-produced articles, The one that is involved here, the material costs represent the main cost factor, is this well-known bottle very expensive.

The object of the present invention is to provide a one-piece container of the type specified in the introduction Kind to be able to manufacture in an economical manner for mass production, with sufficient burst strength and shape retention can safely absorb impact forces even in the face of increased internal pressure and in the case of excessive expansions and reductions in thickness of the material of the container wall also in the bottom area, especially in the area of the standing surface of the container.

This object is achieved according to the invention in that the side walls of each base stand radially from the running transition area to the standing surface diverge upwards in the direction of the container axis and facing side walls of adjacent feet the floor space between one another from the polar cap-shaped area along a dome meridian to the outside to the transition to Limiting the fuselage wall in the form of a rib.

In this embodiment of the container, the feet are determined on all sides by boundary surfaces which - starting from the base - diverge both in the radial direction outward and in the direction of the container axis towards the container opening. As a result, the forces acting on the feet, such as impact forces, are safely introduced over the entire circumference of the container into its cylindrical body wall without the risk of stress concentrations. The boundary walls of the feet, which diverge in both directions, give the feet a resilience that contributes to absorbing the impact forces, without endangering the dimensional stability and stability of the container. Although in a projection of the feet in a perpendicular to the container axis plane of the feet with their Begrenzungsflä <: hen almost the entire bottom surface of the Behälteis constitute, form the band-shaped Bodenzwische ^f "domains that are continuous from the hull on a KalottePfläche to the middle of the Pole cap extend, a radial network of reinforcing ribs, which can safely absorb bursting forces due to their arcuate shape and their location in the middle between adjacent feet. The band-shaped areas also represent the transition between the opposing side winds of adjacent feet.

The divergence of the side walls of the feet also in the axial direction leads to a narrowing of the Circumferential expansion of these band-shaped intermediate floor areas, which gives it the character of arched Ribs preserved. At the same time learns the radially outer boundary wall of each base of the Stand area from upwards a significant increase in the circumferential expansion. This is for the shaping of the Soil is of great importance, because this means that the axial direction stands relatively far for this shape protruding feet on the preform each have a wall area of relatively large circumferential extension to disposal. The consequence is only low stress and a decrease in thickness of the material of the Preform when shaping the feet. This will overuse the material reliably avoided during molding. Since the change in thickness is only relatively small, overall Throw the container made with relatively thin wall thickness. This leads in the context of mass production to a significant saving in material and cost ".

Advantageously, the design is made so that the diameter of the outer boundary wall each pedestal containing envelope surface from the height of the transition point delimited by the side walls between the fuselage wall and the narrow intermediate floor areas towards the stand area steadily decreases This means that all forces absorbed by the feet and the areas between the floors can be absorbed into the same height of the container are introduced into the fuselage wall. It will also be possible to use the Circumferential length of the outer walls of the feet in the transition area to the body wall of the container to make approximately equal to the circumferential length of the fuselage wall, if one uses the band-shaped floor spaces forms sufficiently narrow

The floor is usually designed with more than two feet. This can be one act even or an odd number of feet. The arrangement is preferred, however made that the number of feet is even and their arrangement is symmetrical. The symmetry in the Floor design can facilitate production, especially if this is done with the formation of a floor seam

The invention is explained in more detail below with the aid of schematic drawings of an exemplary embodiment explained.

Show it

1 shows a side view of a bottle made in one piece as plastic according to the invention.

F i g. 2 is a bottom view of the bottle according to FIG. 1 and

F i g. 3 and 4 each in the detail representations of the floor areas in the sectional planes 4-4 and 5-5 of the Fig. 2.

The bottle shown in the figures is used to fill carbonated beverages Bottle is made in one piece from plastic, e.g. B. made of polyethylene. The production can take place in different ways Be done, e.g. B. by vacuum molding, injection molding, injection blow molding or blow molding. Usually is based on a preform produced by extrusion or injection molding, which is in a multipart form is converted into the desired final shape by applying a blowing pressure.

The one-piece bottle has a closed bottom 20 and a substantially cylindrical body 21 of circular cross-section. The bottom 20 goes smoothly or tangentially into the Fuselage wall 21 across.

The bottom 20 is designed profiled and has

several, in the example shown six in the circumferential direction uniformly spaced feet 23, between which each in the middle and in band-shaped floor intermediate regions 22 extending in the radial direction are provided. Although they own individual wall areas of the bottle due to the shape starting from an approximately cylindrical one Small diameter preform by blow molding with wall thicknesses that differ approximately from one another. the However, there are deviations even in the bottom area of the bottle despite the strong profile of the bottom area only slightly.

In the exemplary embodiment shown, the band-shaped intermediate floor areas 22 extend in pairs on a semicircle 24 with approximately the radius of the bottle body 21. With an odd number of feet the band-shaped intermediate regions 22 lie on a common spherical shell-shaped envelope surface. In in each case, the band-shaped intermediate floor areas 22 each extend from a polar cap-shaped area 30 in the middle of the bottom of the bottle.

Each foot 23 ends in a flat footprint 25. The footprints 25 of all feet 23 are in a common level 37. The standing areas 25 are, as shown in FIG. 2 can be seen, of approximately trapezoidal Outline. They can also be described as sectors of a common circular ring area.

From the approximately radially extending lateral boundary lines of the standing surfaces 25 go laterally Boundary surfaces 26 from the common standing plane 37 in the axial direction upwards and from the polar cap-shaped region 30 diverge outward in the radial direction. The two themselves opposite side walls 26 of adjacent feet 23 are on the band-shaped Intermediate floor areas 22 connected to one another, which in the illustrated embodiment are six Feet extend in pairs along a diameter or spherical meridian 32. With the polar cap-shaped In area 30, each standing surface 25 is delimited by a gusset-like wall 27 rising radially inward. In the circumferential area of the bottle, each foot 23 is by one of the foot 25 from upper and outward curved outer wall 28 bounded, which is continuously in the body wall 21 of the bottle transforms.

One recognizes in particular from FIGS. 1 and 2, that the outer wall 28 of each stand 23 in its circumferential extent starting from the standing surface 25 to the transition area into the cylindrical fuselage wall 21 steadily increasing. In the example shown, the sum of the circumferential expansions of the outer walls 28 corresponds at the level of the transition area 36 practically the total circumferential length of the fuselage 21, with this Embodiment, the band-shaped intermediate floor areas 22 at the same height 36 as the Outer walls 28 merge into fuselage wall 21. As in the example shown, the band-shaped Intermediate floor areas 22 be so narrow that they have an almost point-like shape at the transition to the fuselage wall 21 Form transition area 35.

At the transition points between the boundary walls of the feet 23 to the standing surface 25 and to Sharp edges and corners are avoided in the band-shaped floor intermediate regions 22.

Although the feet, as can be seen from the figures, opposite the spherical shell-shaped envelope surface of the band-shaped intermediate regions 22 have a relatively large axial extent, they leave because of the divergence of the boundary surfaces and the large circumferential width of the molding involved peripheral sections of the preform without Overstressing of the material and with only slight changes in wall thickness reliably and very precisely shape. The axial divergence of the side walls 26 of the feet 23 leads to the fact that the floor intermediate areas on the common spherical shell-shaped envelope surface only a relatively small extent in Have circumferential direction or approximately constant width over their length. The intermediate floor areas thus form arcuate reinforcing ribs starting from the polar cap-shaped region 30, which merge steadily and smoothly into the fuselage wall.

Instead of the six feet shown, the bottle can also have four feet or even just two Have feet. An odd number greater than two can also be provided for the feet. In in all cases is the shape of the feet and the connection of the side walls 26 of adjacent ones Feet provided by the band-shaped intermediate floor areas in the same way, in all versions the intermediate floor areas run in opposite directions from the polar cap-shaped area 30 radial directions outward roughly in accordance with meridians on the common hemispherical shell-shaped envelope surface.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Container made of plastic for filling goods under increased pressure, in particular a bottle, with a Hull of circular cross-section and a closed bottom smoothly merging into it, in which the bottom has a central, outwardly convex polar cap-shaped area, at least two hollow feet and between adjacent feet on one to the outside has convexly curved, dome-shaped envelope surface lying bottom intermediate areas, which of the polar cap-shaped area and merge steadily into the fuselage wall, and in which the Feet in a common plane below the polar cap-shaped area and the intermediate floor areas Form horizontal standing surfaces, each standing surface from a gusset-like area rising upwards to the pole cap-shaped area inner partition wall, one outer boundary wall continuously merging into the fuselage wall and two along approximately radially extending Side areas of the stand area outgoing and radially outward diverging and extending up to each adjacent floor intermediate area extending and merging in these side walls is limited, characterized in that the side walls (26) of each stand (23) of the radially extending transition area to the standing surface (25) in the direction of the container axis diverge upwards and the facing side walls of adjacent feet The intermediate floor area (22) on a pole-cap-shaped area (30) along a The calotte meridian extends outwardly to the transition to the trunk wall (21) in a rib-like manner Limit area. 2. Container according to claim 1, characterized in that the diameter of the outer Boundary wall (28) of each stand (23) containing envelope surface from the height of the Side walls (26) delimited transition point (35) between the fuselage wall (21) and the narrow one Intermediate floor areas (22) steadily decreases towards the standing surface (25). 3. Container according to claim 1 or 2, characterized in that the number of feet is an even number and their arrangement is symmetrical.