CS276423B6 - Blown-out integrated plastic bottle for beverages - Google Patents

Abstract

A one piece self supporting blow molded plastic container (130) having a generally cylindrical side wall (138) and a plurality of hollow legs extending downwardly from the side wall. The legs terminate in substantially planar feet (152) having radially outer edges (154) forming a non-continuous support surface engaging area having a diameter slightly less than the diameter of the tubular side wall. A generally horizontal center section (146) is disposed in the center of the container radially inwardly of the legs and merging with the inner edges (156) of the feet. V-shaped ribs extend radially outwardly and upwardly from said center section so as to circumferentially separate said legs.

Description

(57)

276 423 (13) Document kind 86 (51) Int. Cl. ⁵ : β 65 D 1/02

29 C 49/00

B 29 L 22:00

HOOVER UNIVERSAL, INC., MICHIGAN (US)

BEHM FURTHER HERBERT, ALTA LOMA, CALIFORNIA, PLUMMER GEORGE ALLEN, GRAHAM, WASHINGTON (US)

Blown whole plastic beverage bottle

Blown integral plastic self-supporting beverage bottle (130) having a generally cylindrical shape and comprising a bottom (140) with a plurality of hollow legs protruding down from the cylindrical wall (138). The legs are terminated by substantially planar feet (152) with radially outer edges forming a discontinuous contact surface with the support surface and having only a slightly smaller diameter than the diameter of the cylindrical wall (138). In the axis (139) of the bottle (130) there is provided a generally horizontal central bottom portion extending radially outwardly to the hollow legs and adjoining the inner edges of the feet (152). V-shaped ribs extend radially outward and upward from this central portion, separating circumferentially the individual hollow legs. This solution of the bottom of the bottle with hollow legs and feet increases the stability of the bottle when filling it with a carbonated beverage.

CS 276423 B6 '

The invention generally relates to blown solid plastic beverage bottles and, more particularly, to an improved bottle of this type comprising flat bearing horizontal surfaces of enlarged surface, keeping the bottle firmly upright when being filled.

The main difficulty in using plastic bottles for carbonated beverages is the bottom strength of the bottle. When filling a bottle with a carbonated beverage, plastic bottles tend to bulge on the bottom under internal pressure, which may be greater than 0.5 MPa, resulting in a phenomenon referred to as labile support causing the bottle to tilt when placed on a flat surface to the sides or even flip. In addition, when the bottom bulges, the volume of the bottle is increased, thereby lowering the filling level so that the consumer may believe that the bottle has not been properly filled or sealed.

One solution to the problem of buckling the bottom is to make the bottle such that it comprises a lower spherical portion to which a support cup having a flat bottom surface for holding the bottle in a vertical position is attached. This type of bottle is commonly referred to as a composite bottle. Such composite bottles of 450 grams or more are widely used for carbonated beverages. However, an increase in the material cost of producing the support cups is the reason for the development of integral bottles with self-supporting bottoms reinforced to resist bulging under the saturation pressure of carbon dioxide.

There are several factors to consider when dealing with such a bottle bottom. One of the most important factors is the stability of the bottle. The bottle must be stable when empty and filled. The empty bottle must be sufficiently stable to stand in the filling device. If the bottle were tipped during displacement, the filling operation would be adversely affected. In order to ensure the stability of the bottle, the diameter of the bearing surface of the bottle bottom in contact with the supporting horizontal surface must be maximized. Also, the bottom abutment surface in contact with the support surface must be maximized.

Another evaluation factor is the strength of the bottom so that after filling the bottle it can withstand bursting on impact. The strength of the bottom is reduced by stress cracking, which results in its easy rupture. The extent of stress cracking is dependent on the bottom geometry. Stress cracking can be reduced by relatively large radii of curvature compared to a bottom with small radii of curvature.

Another consideration is the correct venting capability of the mold cavities when blowing the bottle. They must be sufficiently vented to ensure that the plastic material is fully pushed into each foot of the bottom so that the feet are formed at the lower ends of the bottom of the foot. the bearing surfaces of the bottle in contact with the support surface.

A series of solid plastic beverage bottles has been developed. However, these bottles exhibit one or more disadvantages related to their bottom structure. The bottom structure of the plastic bottle bends downwards when filled with a carbonated beverage. Since this occurs with most existing solid plastic bottles, this reduces the diameters and dimensions of their bearing surfaces, resulting in reduced stability of the bottle when filling.

Some existing plastic bottles also have a bottom geometry with small feet and relatively small radii of curvature. This results in unstable support and stress cracking, thereby reducing the strength of the floor and increasing the possibility of the floor breaking when impacted.

CS 276423 Β 5

Based on this brief evaluation of existing plastic bottles, it is an object of the invention to provide a plastic beverage bottle with flat bearing surfaces in contact with the support surface and having enlarged dimensions and only a slightly reduced diameter relative to the bottle diameter to increase bottle stability. It is another object of the present invention to provide a plastic beverage bottle in which a bulging surface in contact with the support surface would not be reduced by bulging the bottom when filling it. It is also an object of the invention to provide a bottle with larger transition radii and curvature curves to reduce the possibility of stress cracking.

The object of the invention was achieved by solving a blown whole plastic beverage bottle of cylindrical shape for carbonated beverages, whose bottom structure according to the invention comprises a bottom wall extending radially inwardly from the lower end of the cylindrical wall of the bottle. In this case, a plurality of hollow legs protruding downward from this bottom wall of the bottom ending in wide planar feet with radially outer and inner edges.

The outer edges of the feet form a discontinuous bearing surface for contact with the support surface, the diameter of the outer edges being only slightly smaller than the diameter of the cylindrical wall of the bottle.

A further improvement is that the beads can be inclined radially inwards and upwards so that when the bottle is supported on a horizontal support surface, the outer edges of the beads are in contact with the horizontal support surface and the inner edges of the beads are above this support surface. the feet rotated downwardly around their outer edges to substantially horizontal positions in which the feet are in flat contact with the support surface in response to the internal pressure into a bottle of filled carbonated beverage. In the horizontal position, the feet provide wide contact surfaces with the support surface on which the bottle is built. When filling the bottle, the diameter of the contact surfaces does not decrease as a result of internal pressure, as is the case with most existing bottles when filling. When filling the bottle, the outer edges of the feet remain in contact with the horizontal support surface, the contact surfaces of the feet in contact with the support surface having a diameter equal to that of an empty bottle.

The legs of the legs extending downwardly from the bottom wall of the bottom are preferably tapered inwardly from being bonded to the cylindrical wall of the bottle. This conical taper is necessary to allow the production of the plastic bottle. When the conicity is reduced to the minimum necessary, the radial distance from. the axis of the bottle to the outer edge of the feet is maximized, resulting in a relatively large diameter of the abutment surfaces of the feet in contact with the support surface. This increases the stability of the bottle. In addition, a larger diameter bottom at its lower end allows an increase in the planar surface area of the feet as compared to existing plastic bottle designs.

Furthermore, it is expedient to increase the radius of curvature of the bottom profile with an increased diameter of the contact surface in contact with the carrier sheet, thereby reducing the stress cracking of the bottom.

Further useful characteristics and advantages of the plastic beverage bottle according to the invention will become apparent from the following detailed description of the invention, made with reference to the figures, which show: Fig. 1 - partial sectional view of the bottom of a plastic beverage bottle in an earlier embodiment; FIG. 2 is a partial cross-sectional view of the bottom of a plastic beverage bottle in another prior embodiment; Fig. 3 is a front view of the plastic beverage bottle according to the invention; Fig. 4 - a bottom view of the bottle according to Fig. 3; FIG. 5 is a sectional side elevational view taken at section 5-5 of FIG. 4; FIG. 5A is an enlarged fragmentary view of a portion of the bottom of FIG. 5; FIG. 6 is a front view of a modified shape of a plastic beverage bottle according to the invention; FIG. 7 is a side view of the bottle of FIG. 6, with another bottom position; FIG. 8 is a plan view of the bottle of FIG. 6 and 7; FIG. 9 is a bottom view of the bottle of FIGS. 6 and 7; FIG. 10 is a partial cross-sectional view of the bottom of the bottle in the direction 10-10 of FIG. 9.

FIG. 1 shows a variant of an embodiment of the bottom of a plastic beverage bottle in an earlier embodiment. The bottom 102 includes a plurality of horizontal feet 104. The outer edges 105 of the feet 104 define the outer diameter D of the bottle surface that is in contact with the support surface while the bottle is empty. The middle portion 106 closes the bottom 102 between the inner edges 107 of the feet 104. This middle portion 106 of the bottom 102 is bent inside the bottle to form a concave bottom wall.

When this plastic beverage bottle, standing on the feet 104, is filled with a carbonated beverage, the pressure in the bottle acts on the bottom bottom portion 106 to bulge, thereby forming a bottom-shaped 108 pattern, indicated by dashed lines, simultaneously causing the feet 104 to be bent around their edges 105 to position 110, also indicated by dashed lines. In this position, the bottle is then supported on the support surface by a bearing diameter, corresponding to the inner edges 110 of the feet 104. The diameter is substantially smaller than the original bearing diameter D, thereby reducing the stability of the bottle during filling.

FIG. 2 shows another embodiment of the bottom of a plastic beverage bottle in an earlier embodiment. The bottom 112 comprises horizontal feet 114 and ribs 116 extending from the inner edges 118 of the feet 114 transversely to the opposite wall of the bottle and adjoining thereto by curvature 120 The surfaces of the feet 114 of the bottom 112 abutting the bearing surface have a diameter defined by the outer edges 122 of the feet 114 However, when the bottle is filled with a beverage saturated with carbon dioxide, the bottom 112 is bent downwardly by the pressure in the bottle so that the initially straight ribs 116 are now bulged, as shown by the dashed outline 124. This results in bending of the feet 114 generally around their outer edges 122 to a dashed position 126. In this position, the diameter of the contact surface of the bottom 112 abutting the support surface is limited only by the inner edges 12 of the bent feet 16. again reducing the stability of the filled bottle to the empty bottle.

Fig. 3 shows a basic embodiment of a plastic beverage bottle 130, the bottom of which is constructed according to the invention. The bottle comprises a bottom 140 in which, even when the bottle is being filled, the diameter of the contact surface of the bottom with the supporting surface does not decrease. The bottle 130 is made by blowing out of a bi-directional saturated polyester, preferably polyethylene terephthalate (PET). It comprises an upper tapered portion 132, extending into a tapered neck with a flange 134 and a threaded neck 136. This tapered upper portion 132 is adjoined by a downwardly extending hollow body delimited by a cylindrical wall 138 with a vertical axis 139. closing the bottom of the bottle 130.

The bottom 140 is formed by a downwardly extending bottom wall 142, shown more clearly in FIG. 5. This bottom wall 142 is curved radially inwardly from the lower end of the cylindrical wall 136, as shown in FIG. 5, the bottom wall 142 is formed by an arc of constant radius of curvature. which is greater than the radius of the cylindrical wall 136. The upper end of the bottom wall 142 is connected to the lower end of the cylindrical wall 138 by a relatively small radius of curvature 144. The lower wall 142 is terminated at its lower end. This central portion 146 is substantially horizontal in the middle of the bottom 140, although it may be slightly concave or convex.

The bottom wall 142 of the bottom 140 is interrupted by a plurality of downwardly projecting wall portions defining hollow legs spaced radially around the central portion 146 and projecting below the bottom wall 142. These wall portions form side walls 148 and outer walls

3. The outer wall 150 of the legs forms radially outer surfaces of the hollow legs. As shown in Figures 3 and 5, the outer walls 150 of the legs are arcuate, with a constant radius of curvature extending radially inwardly downward. The side walls 148 of the legs extending downwardly and radially inward from the bottom wall 142 of the bottom 140. The legs are terminated with the beads 152. FIG. 5A shows an enlarged view of the bead portion of FIG. 5. Each, bead 152 is planar and generally trapezoidal in shape, its outer edge 154 being generally parallel to the inner edge 155 (FIG. 4). ). The side edges 155 of the feet 152 extend obliquely downwardly, radially inwardly. The bottom wall 142 forms an inverted V-shaped rib along the circumference between the hollow legs, by which the legs are separated.

Each shoe 152 defines a planar surface inclined radially inwardly upwardly so that the outer edge 154 of each shoe 152 is lower than its inner edge 156. The outer edges 154 of the shoe 152 adjoin the lower ends of the outer wall 150 feet and are joined thereto by a portion 158 of relatively small radius · fillet. The outer edges 154 of the feet 152, having only a slightly smaller diameter than the diameter of the cylindrical wall 138 of the bottle 130, form regions abutting the support surface 163. By placing the outer edges 154 of the feet 152 as radially outward as possible, the stability of the bottle is improved.

When filling the bottle 130 with a carbonated beverage, the pressure inside the bottle will center the bottom portion 146 of the bottom 140 bulging downward to the position indicated in FIG. 5 by the dashed outline 160 As a result of the bulging of the center portion 146 the feet 152 also move downwardly so that In this pivoted position 162, the feet 152 are now in contact with the horizontal abutment surface 163 on which the bottle 130 is erected. The outer edge of the contact surfaces remains such that the diameter of the surfaces abutting the bearing surface 163 is not reduced by the bulging of the central portion 146. The stability of the bottle is therefore not reduced when filling.

The angle 157 below which, when the bottle 130 is empty, its heel 152 is inclined from the horizontal bearing surface 163 is dependent upon the size of the bottle and the thickness of the bottom wall material. These two factors define the extent of the bottom bulge caused by the internal pressure when filling the bottle. It has been found that for most 2 liter and 0.45 liter bottles, an angle of 157 with an inclination of about 9 ° is sufficient,

In addition to maintaining the stability of the bottom 140 of the bottle 130 as it bulges, the contact surface of the feet 152 with the support surface 163 limits the roll of the bottle. A standing bottle swings on impact unless the impact is hard enough to tip the bottle. This nod is then muted and the bottle remains standing. When the bent feet 162 are in contact with the support surface 163, the flare attenuation of the filled bottle is greater than that of the bottle empty, supported only by the outer edges 154 of the inclined feet 152.

Another embodiment of a bottle according to the invention is shown in Figs. Referring again to FIG. 10. This is a blown, integral plastic beverage bottle, generally designated 10. The bottle 10 includes an upper conical portion 13 extending into a cylindrical neck with a flange 12 and a threaded neck 18. The conical portion 13 passes down into a hollow cylindrical wall 14 of the bottle. and the bottom 16.

As shown in FIG. 10, the bottom 16 comprises a bottom wall adjoining the cylindrical wall 14 and formed by an upper portion 20 and a lower portion 30 radially inwardly curved downwardly. The bottom wall terminates in a central portion 28 forming substantially the center of the bottom 16. . '

CS 276423 B'6

The bottom wall is interrupted by a plurality of downwardly extending wall portions defining hollow legs 26 projecting from the bottom wall. These wall portions comprise the side walls 32 and the outer walls 33 of the hollow legs 26. As shown in FIG. 1D, the outer walls 33 of the legs 26 extend downwardly slightly conical inward to form radially outer surfaces of the hollow legs 26. The legs 26 terminate with planar feet 25 (FIG. 10) adjoining the central portion 28 of the bottom 16 The feet 25 are inclined radially inwards upward as indicated in FIG. 10 by a dashed outline showing the position of the feet 25 with the empty bottle 10 standing. which they assume when filling the bottle 10 with a carbonated beverage. When filling the bottle 10, the feet 25 generally pivot around their outer edges 24 to a position 27 in which the feet are in full surface contact with the horizontal support surface 29.

In both embodiments of the plastic beverage bottles according to the invention comprising feet as spaced as radially outward as possible, it is possible for the feet to comprise relatively large planar surfaces forming contact surfaces with the support surface. The outer walls of the legs extend slightly conical or rounded radially inwardly downwards to facilitate removal of the blown bottle from the mold. This cone or rounding is minimized to the minimum necessary so that the diameter of the discontinuous contact surface of the feet with the support surface formed by the outer edges of the feet is only slightly smaller than the diameter of the cylindrical wall of the bottle. In addition, this arrangement allows the design of relatively large radii of the rounded portions of the bottom compared to a number of prior art plastic beverage bottles, thereby reducing or even eliminating the possibility of stress cracking of the bottom. It has been found that for 2-liter and 0.45-liter bottles, the optimum number is five feet to provide larger feet and large radii of rounding off the bottom.

The plastic beverage bottles 10 and 130 of the present invention are manufactured in a conventional manner by blow molding from injection molded plastic preforms. The preform is heated to a temperature at which it can be blow molded and then inserted into a mold cavity whose inner surface corresponds to the desired bottle shape. Compressed air is then introduced into the parison to spread the parison laterally into contact with the inner surface of the mold cavity. Air from the mold cavity is sucked through the vent slots provided in the lower portion of the mold cavity to allow the plastic material to be perfectly blown into the foot portions of the lower mold cavity. These vent slots are formed in the form of narrow grooves in the mold cavity, forming narrow but noticeable lines on the surface of the bottle feet, indicated in FIG. 4 as lines 172, in FIG. 9 as lines 34 and in FIGS. 6 and 7. as lines 36.

The hollow legs are formed by blowing the bottom wall plastic material down from the bottom wall. The legs are terminated by substantially flat contact surfaces with a support surface concave from the bottom wall. When the bottle is filled with carbonated beverage, the inclined contact surfaces of the feet of the bottle rotate around their edges under internal pressure in the bottle to form planar running surfaces with a horizontal bearing surface so as to be supported on the bottle in the upright position.

The invention provides a blown integral plastic beverage bottle with a self-supporting bottom. The bottom comprises a bottom wall extending from the lower end of the cylindrical wall of the bottle. A plurality of hollow legs with flat feet protruding from the bottom wall are inclined. from the outer edges of the legs radially inwards upwards. When filled with a carbonated beverage, the internal pressure in the bottle bulges the bottom wall, whereby the feet are also pivoted to a horizontal position defining the plane of contact with the support surface for supporting the bottle in the upright position. This bulging does not result in a reduction in the diameter of the contact surfaces with the support surface, thereby reducing the stability of the standing bottle when filling. In addition, the bottom of the bottle is shaped with relatively large radii rounded

CS 276423 Bg parts, thereby reducing the extent of stress cracking of the bottom and tf.m increasing the strength of the bottom and reducing the possibility of tearing.

It is to be understood that the invention is not limited to the illustrated and described embodiments or method of manufacture, but that various modifications and modifications are possible without departing from the spirit and purpose of the invention as defined by the subject matter of the invention.

Claims (10)

PATENTOVĚ Claims A blown, solid cylindrical plastic beverage bottle for carbonated beverages, characterized in that its bottom structure (16, 140) comprises a bottom wall (20, 142) extending from the lower end of the cylindrical wall (14, 138) of the bottle (16). 10, 130) downwardly radially inwardly, a plurality of hollow legs (26) projecting downwardly from this bottom wall (20, 142), terminated by wide planar feet (25, 152) with radially outer edges (24, 154) and radially inner edge (1561) such that the radially outer edges (24, 15.4) define a discontinuous bearing surface for contact with the support surface (29, 163), the diameter of the radially outer edges (24, 154) being only slightly smaller than the diameter of the cylindrical wall 14, 138 / bottles / 10, 130 / » 2. A blown unitary plastic beverage bottle according to claim 1, characterized in that the feet (25, 152) are inclined radially inwards upwards such that when the bottle (10, 130) on the horizontal support surface (29, 163), the radially outer edges (24, 154) of the feet (25, 152) are in contact with the horizontal support surface (29, 163), thereby allowing the feet (25, 152) to pivot in response to the internal pressure of the carbonated beverage and filled into the bottle (10, 130) down the knee of its radially outer edges (24, 154) down to the substantially horizontal positions (27, 162) in which the feet (25,152) are in flat contact with horizontal support surface (29, 163). Blown whole plastic beverage bottle according to claim 1 or 2, characterized in that the hollow legs (26) comprise outer walls (33, 150) extending from the cylindrical wall (14). 138) of the bottle (10, 130) downwardly and adjoining the radially outer edges (24, 154) of the feet (25, 152), the outer walls (33, 150) tapering slightly conically downwardly radially inwardly. 4. A blown unitary plastic beverage bottle according to claim 3, wherein the outer walls (33, 150) of the hollow legs (26) are formed by a substantially constant radius of curved portions radially inwardly downwardly from the cylindrical wall (14, 138). Blown unitary plastic bottle according to claim 1 or 2, characterized in that the bottom wall (20, 142) comprises a substantially horizontal wall portion (28, 146) extending radially outwardly from the axis (139). a bottle (10, 130) and adjoining the inner edges of the feet (25, 152). 6. Blown whole plastic beverage bottle according to claim 1 or 2, characterized in that the wall (20, 142) of the bottom (16, 140) is rounded, Blown unitary plastic beverage bottle according to claim 6, characterized in that the wall (20, 142) of the bottom (16, 140) has a substantially constant radius of curvature. Blown whole plastic beverage bottle according to claim 1 or 2, characterized in that the hollow legs (26) are defined by outer walls (33, 150) running downwardly from the cylindrical wall (14, 138) of the bottle (10,130) 'and the adjacent outer edges (24, 154). feet (25,152), and a side wall doublets (32,148) extending from the wall (20, 142) of the bottom (16, 140) downwardly and radially inwardly from the outer walls (33, 150), the side walls (32, 148) of the adjacent hollow legs (26) and the wall (20, 142) of the bottom (16, 140) forming inverted ribs The hollow legs (26) are separated therefrom. 9. A blown unitary plastic beverage bottle according to claim 1 or 2, wherein the feet (25, 152) are generally trapezoidal in shape. Blown whole plastic beverage bottle according to claim 1 or 2, characterized in that the bottom structure (16, 140) comprises five hollow legs (26) with feet (25, 152).