RU2127213C1 - Cellular container for bottles - Google Patents

Abstract

FIELD: storage, transportation and sealing of bottles. SUBSTANCE: container moulded from plastic in form of solid unit has bottom and walls arranged vertically relative to bottom over periphery of bottom. Bottom has open lattice structure and includes bottle support zones. lower surface of bottom is shaped to provided fitting in of upper parts of bottles placed in other similar container arranged below. Walls have lower part adjacent to bottom and large number of pylons made integral with wall arranged over periphery of cellular container. Lower part of wall is twin structure, with hollow pylons made integral with twinned part of wall. Pylons pass at angle to inner part of cellular container and are tapered to make their cross section smaller in upper part and larger near lower part of wall to provided fitting of pylons of empty containers one into the other. EFFECT: possibility of fitting-in containers one into the other with sufficient strength, unobstructed observation of bottles. 20 cl, 19 dwg

Description

 The present invention relates to a cellular container that can be inserted into another container of the same type and is intended for transporting and storing containers, and more specifically, the present invention relates to cellular containers or trays that combine the possibility of stacking them and high strength with a good overview for demonstrations of bottles.

 Bottles, in particular for soft drinks and other drinks, are often stored and transported in cellular containers or in trays during their sale. The term “cellular packaging” as used herein encompasses cellular boxes, trays, or similar supports having a bottom and peripheral side walls. These honeycomb structures are usually configured so that, when loaded with bottles, they can be stacked on top of one another and fit into each other when there are no bottles. Plastic honeycomb structures provide benefits such as saving storage space, efficiency and ease of handling, and reusability. In order to minimize the space required for storing the honeycomb container when it is inserted into each other, as well as reduce the cost and weight, nowadays, cellular trays are often made with a low design of the peripheral side walls. They are commonly referred to as “shallow mesh containers” in which the bottles carry most of the load from containers that are stacked on top. Cellular containers having higher peripheral side walls, approximately the same as the height of the bottle, are called "full-depth cellular containers", and these containers themselves bear most of the load from the containers that are laid on top.

 Shallow cellular containers are usually cheaper and have less weight than full-depth containers. Therefore, shallow containers are used very widely. Usually a shallow mesh container is made with a large number of columns connecting the upper rim to the bottom. An example of such a shallow canned food tray is disclosed in US Pat. No. 5,184,748, the contents of which are incorporated herein by reference.

 The tray disclosed in US Pat. No. 5,184,748 is an insert tray, which means that identical empty trays can be inserted into each other to save space when they are sold or stored.

 Another example of a known shallow cellular packaging for single-use bottles is disclosed in US Pat. No. 5,060,819, the contents of which are incorporated herein by reference. The honeycomb bottle container according to US Pat. No. 5,060,819 has side walls of equal thickness with adjacent vertical panels, part of which are alternately raised so that their lower surfaces are spaced from the bottom. In this case, the upper and lower edges of the side wall have a wavy configuration, due to which the empty trays can be inserted into each other.

 Disposable bottles, usually using a filling machine, are placed in boxes or other containers, several bottles per box, for transport to a point of sale or storage. Boxes with bottles are usually stacked on top of each other. One way to manipulate bottle boxes is to stack the boxes in a stack on pallets that can be lifted and moved by forklift trucks. The technology of tying foot boxes, called "cross-stack", is often used to increase the stability of the stack of boxes, or to improve their visibility of the seller. There is a need to create bottle containers with design features that facilitate the handling of loaded boxes stacked in a cross-stack stack, increase the stability of the stack of boxes and provide an opportunity for an optimal view of the bottles, especially if they are put up for sale. One of the problems associated with the known cellular packaging, inserted into each other, in particular in the case of single-use bottles, is the lack of strength when used under certain conditions. For example, the tray according to US patent N 5060819 has a wall of constant thickness, which over time may not withstand rough loading and unloading. Accordingly, there is a need for reusable, interposable cellular containers having the required strength and stiffness to withstand repeated or rough loading and unloading operations.

 Another problem inherent in known cellular containers is the limited visibility of the bottles or their labels. Although pallets with columns and rims, which are disclosed in US Pat. No. 5,184,748, provide the ability to view many labels, the rim to some extent impedes the view of the bottles. Similarly, the wavy side wall of a pallet according to US Pat. No. 5,06819 leads to some interruption in visibility. There is a need for a cellular container that is strong enough, but does not limit the visibility of the bottles in this hardened structure.

 In many cases, bottles with the same or similar capacity may have different sized tops. There is a need for a container that can reliably engage with differently sized bottle tops located in a similar container below.

 Accordingly, the main objective of the present invention is to provide a shallow cellular container for bottles that can be inserted into another similar container when not loaded to save space, and which can form a stack (cross-stack) with other cellular containers when they are loaded bottles or tanks for their storage, demonstration and transportation. The cellular packaging according to the invention contains distinctive features that enable the insertion of empty cellular packaging into each other and its stable stacking, as well as the cross-stack of the loaded cellular packaging.

 Another objective of the present invention is to create a shallow cellular packaging, which can be inserted into another container and has sufficient structural strength to withstand repeated and rough loading and unloading.

 Another objective of the invention is to create a strong and shallow cellular containers, which can be inserted into another of the same containers, and also provides maximum visibility to the bottles and tanks when they are shown.

 Another objective of the present invention is to create a shallow cellular packaging that can be inserted into the same container and provides efficient use of space in the case of loaded containers and stacking them, and in the case when the container is empty and inserted into each other . When the cellular packaging is loaded and stacked, the packaging design of the invention also provides reliable engagement with the upper parts of bottles having different sizes of the upper parts.

 The new shallow cellular packaging for bottles presented here, which can be inserted into another container of the same type, is aimed at achieving these objectives. The preferred configuration is for sixteen to twenty ounce disposable bottles (474-592 ml). It is clear that although the presented embodiment of the container construction according to the invention has a configuration for storing bottles, cellular packaging can be used for storage and transportation of any type of containers. Such a cellular container is formed by molding from plastic in one piece two main components - the bottom and the wall structure, extending upward from the bottom and passing around the periphery of the bottom.

 The bottom preferably has an open lattice structure, which not only allows drainage of unwanted liquid from the container, but also requires less material, and therefore is easier than a solid bottom structure. The bottom has reservoir holding zones, preferably arranged in a row.

 The bottom of the honeycomb container has an outer or bottom surface, which is configured to accommodate the upper parts of the bottles in another container below. The bottom surface facing the floor preferably has recessed receiving zones facing upward and arranged so that the upper parts of the bottles contained in another container located below come into them. Reception areas help to keep the bottles upright, which increases the stability of the stacked loaded cellular containers. As for this distinguishing feature, each of the receiving zones is designed so that the upper parts of the bottles of at least two different sizes come into them. Reception areas also prevent the containers from sliding freely on the top of bottles located in another container located below. The peripheral surfaces of the receiving zones are beveled to allow the container to detach from the top of the bottles when the container is rotated around the vertical axis, so that immediately after uncoupling the container can slide along the upper parts of the bottles in the lower container to facilitate loading and unloading.

 The wall structure contains a lower part adjacent to the bottom, and a large number of pylons formed in one piece with it and located around the periphery of the bottom of the cellular packaging. Obviously, the term “pylon” means hollow posts or uprights extending upward. The lower part of the wall is a double-wall structure, since hollow pylons are naturally suitable for their formation in one piece with such a double bottom part of the wall. The hollow pylons preferably extend at an angle towards the inside of the honeycomb container and taper in such a way that they are smaller in cross section in the upper part and larger in the lower part of the wall so as to enable the pylons of the empty container to be inserted into each other.

 Preferably, the pylons are located around the periphery of the bottom of the cellular packaging. One pylon is located in each corner and one pylon is located between adjacent supporting areas of the bottom, so that in the container profile it resembles the teeth of a saw, as shown in FIG. 1 and 2. The bottles loaded in the container are visible through the openings between the pylons, as shown in FIG. 16-18. The cellular packaging according to the invention combines the advantages of a cellular packaging that can be inserted in the same packaging with the sufficient strength provided by the double-walled construction with a maximum view of the bottles without interference.

 These and other features and advantages of the invention may be better understood from the following detailed description of a preferred embodiment of the invention with reference to the accompanying drawings.

Brief Description of the Drawings
FIG. 1 is a vertical view of a side wall of a cellular packaging according to a first preferred embodiment of the invention.

 FIG. 2 is a vertical view of the end wall of the cellular packaging according to FIG. 1.

 FIG. 3 is a plan view from above of the cellular packaging according to FIG. 1.

 FIG. 4 is a bottom view of the cellular packaging according to FIG. 1.

 FIG. 5 is a cross-sectional view of the cellular packaging of 5-5 in FIG. 3.

 FIG. 6 is a cross-sectional view of the cellular packaging of 6-6 in FIG. 3.

 FIG. 7 is a cross-sectional view of the cellular packaging of 7-7 in FIG. 3.

 FIG. 8 is a cross-sectional view of the cellular packaging of 8-8 in FIG. 3.

 FIG. 9 is a cross-sectional view of the cellular packaging of 9–9 in FIG. 3.

 FIG. 10 is a cross-sectional view of a cellular container of 10-10 in FIG. 4.

 FIG. 11 is a cross-sectional view of the cellular packaging of 11-11 in FIG. 4.

 FIG. 12 is a cross-sectional view of the cellular packaging of 12-12 in FIG. 3.

 FIG. 13 is an enlarged detailed view of a zone 13 shown in FIG. 3.

 FIG. 14 is a detailed perspective view of a cut-out of the corner zone of the cellular container according to FIG. 1.

 FIG. 15 is a fragmentary cross-sectional view similar to that of FIG. 5, of the cellular packaging according to FIG. 1 inserted into an identical empty container.

 FIG. 16 is a perspective view of a cellular container according to a second preferred embodiment of the invention loaded with bottles arranged in four rows of three pieces in each row.

 FIG. 17 is a perspective view of a cellular container according to a third embodiment of the invention loaded with bottles in five rows of three pieces in each row.

 FIG. 18 is a perspective view of a cellular container according to a fourth embodiment of the invention loaded with bottles in five rows of three pieces in each row.

 FIG. 19 is a schematic perspective view of a cut-out of a wall structure of a cellular container according to FIG. 16 and 17 in the area of the handle.

Detailed Description of Preferred Embodiments
The present invention provides a shallow cellular container that has distinctive design features that provide sufficient strength, facilitate the insertion of empty cellular containers into each other, the stable stacking and cross-stack of loaded containers, and also allow for a maximum view of bottles or tanks. The present invention is most applicable to disposable bottles made of both glass and plastic.

 Referring to FIG. 1 and 2, the cellular container 20 contains two main elements: the bottom 22 and the wall structure 24. The wall structure, which forms the periphery of the cellular container 20, contains a lower part 26 and a large number of pylons, including corner pylons 28 and side pylons 30 and 30a. Cellular container 20 is preferably rectangular in shape and the wall structure comprises side walls 25 and end walls 27. Although rectangular cellular containers are described and shown, the present invention is not limited to them and may contain side and end walls of equal length, resulting in a square cellular container .

 The bottom 22 preferably has a trellised configuration, the structure of which includes open spaces, as shown in FIG. 3 and 4, which show the types of bottom, respectively, above and below. The open bottom design provides a lightweight cellular packaging and its practicality, since it provides the possibility of draining through the bottom 22 of any liquid. Typically, the bottom is open and flat so as not to impede auxiliary wrapping materials or strapping means passing around a large number of bottle containers such as a plastic wrap.

 Referring to FIG. 1-4, the bottom 22 has an upper surface 32, which is usually flat and which includes a plurality of, preferably circular, support zones or rings 34, for holding bottles on them. At the corners of the honeycomb container 20, angular support zones 35 are located, which in almost all respects are similar to the support zones 34 and are described in more detail below. The support zones 34 and 35 are connected to each other by a system of mesh longitudinal ties 36 and transverse ties 38 extending along the bottom perpendicular to each other, as well as diagonal ties 40, preferably extending from the support zones 34 in the radial direction. The intermediate lattice elements 42 are preferably circular elements located between the support zones 34 and 35 and made integrally with longitudinal, transverse and diagonal ties. The perpendicular ties 36 and 38 usually extend along the entire length and width of the bottom 22, and connect the rows and columns of the support zones 34, as well as the corner support zones 35. Some perpendicular ties 36 and 38 are connected radially to the round lattice elements 42. The diagonal ties 40 are radially connected the lattice elements 42 and the support zones 34 and 35. The lattice elements 42 are preferably the same size, with the exception of three large circular lattice elements 43 located along the longitudinal axis of the cellular packaging from the end wall to the end wall. The central grid member 43a in FIG. 12 is shown in cross section, where it is the preferred location of the injection point 44 in the manufacture of injection molded cellular containers 20.

 Support zones 34 and 35 are arranged in rows and columns to thereby form one or more rows. In one preferred embodiment of a four-row design with six places in a row, twenty-four bottles of sixteen or twenty ounce (474-592 ml) capacity are accommodated. In other preferred embodiments, one-liter bottles in the amount of twelve pieces can be arranged in three rows of four pieces in a row, or in the amount of fifteen pieces in three rows of five pieces in a row. The support zones 34 are configured so that the bottles in a row are held relatively close to each other so as to prevent their collision during loading and unloading operations. Excessive bottle movement should be avoided to ensure that the bottles remain upright to predominantly hold the load from the bottles that are higher and stacked or cross-stacked.

 Each support zone or ring 34, 35 is dimensioned so that bottles are installed in them, while they are connected to other support zones by perpendicular ties 36, 38 and diagonal ties 40. The support zones 34 and 35 preferably have solid, generally flat surfaces moreover, the support zones around the periphery of the cellular packaging have drainage holes 46. In FIG. 13 is a detailed view of a portion of the corner support zone 35 — the zone marked in FIG. 3.

The bottom 22 has a bottom surface 48 having a distinctive design feature. The bottom surface 48 of the bottom is configured to allow stacking, as well as the ability to cross-stack loaded honeycomb containers. The cross-stack of containers is performed by rotating the upper packaging 90 ^o around the vertical axis and lowering it onto the lower packaging or containers. During the transportation of the honeycomb containers or the handling of them, they can be moved by mechanisms, and it is preferable to use cellular containers that can be stably stacked in a stack or cross-stack. In addition, when cellular containers are used to demonstrate tanks for sale, the seller may wish to stack the cellular containers in a cross-stack for demonstration purposes or for spacing.

 The bottom bottom surface 48 has a plurality of upwardly extending recessed areas 50 for receiving the upper parts of the bottles, which is best shown in FIG. 4, 6 and 11. The periphery of the recessed receiving zones 50 are formed by circles 52 and arcs 54, which are molded in one piece with the bottom surface 48 of the bottom and form part of it. The positions of the circles 52 and arcs 54 are selected so as to provide a range in which the upper parts of the bottles in the bottom loaded container can remain and still provide safe stacking, as well as their cross-stack. Reception areas 50 help to keep the bottles upright to withstand the load from the bottles above and stacked or cross-stacked. Generally speaking, the peripheral receiving zones 50 are those zones that are adjacent to the wall structure formed by the arcs 54, and the central receiving zones are formed by circles 52. The receiving zones 50, which are centered on the bottom surface of the bottom, are less offset from the corresponding support zones 34 than those that are closer to the wall structure. A detailed cross section of a portion of the circle 52 is shown in FIG. ten.

 The peripheral surfaces of the receiving zones 50 are beveled surfaces 56. In stacking or cross-stacking positions, the receiving zones prevent the cellular containers from sliding freely along the upper parts of the bottles located in the lower cellular containers, and as soon as the receiving zones depart from the holding positions, t .e. positions when stacking or cross-stacking, the upper cellular packaging slides along the upper part of the bottles located in the lower cellular packaging, to facilitate loading and unloading. Bevels 56 allow the approach of the honeycomb container 20 to the upper parts of the bottles in the lower honeycomb container when the upper container is slightly rotated around a vertical axis.

 A detailed cross section of the receiving zone 50 is shown in FIG. 11. A detailed view of the receiving zone 50 in FIG. 11 shows that this is more than a simple recess. The receiving area 50 is designed to accommodate the upper parts of the bottles of more than one size. In fact, there are two concentric receiving zones — the outer zone 50a and the inner zone 50b. In the first embodiment, the outer zone 50a is formed by a tapered surface 56 around the periphery of the receiving zone 50 and can accommodate the top of the bottle having a diameter of 38 mm. The area directly inward from the bevel 56 is preferably a flat area 57 and in the first embodiment, its width is preferably 5 mm. The inner zone 50b is preferably defined by a spherical surface 58, the edge of which is concentric with the bevel 56. The spherical surface 58 is more deeply recessed upward than the receiving zone 50, and in the first embodiment is in tight engagement with the upper part of the bottle having a diameter of 28 mm. The edge of the spherical surface 58 can facilitate the detachment of the upper part of the bottle, which is located below, for sliding the honeycomb containers along the upper parts of the bottles. Obviously, although dimensions may vary, for other preferred embodiments, the inner and other receiving zones are constructed as described above with appropriate proportionality for a particular mesh container.

 The honeycomb container 20 of the invention holds relatively closely spaced packed bottles, the container being able to slide along the top of the bottles. Due to the close arrangement of the bottles during packaging, a tendency to greater vertical stability is ensured.

 The wall structure 24 defines the periphery of the honeycomb container 20 with opposite side walls 25 and opposite end walls 27.

 The wall structure 24 comprises a lower part 26, the inner part 60 of which is made integrally with the floor 22. The corners of the cellular packaging 20 are rounded and made integrally with the lower part 26 of the wall. A corner pylon 28 is formed in each corner 20. A large number of side pylons 30 and 30a are located along with the corner pylons along the side walls 25 and the end walls 27. All pylons 28, 30 and 30a are formed integrally with the lower part 26 and with the floor. Pylons 28, 30 and 30a are preferably hollow, and they extend from the floor up and beyond the upper surface of the lower wall 26 of the wall. In order to enable the insertion of empty cellular containers into one another, the pylons 28, 30 and 30a preferably extend at an angle towards the inside of the container and taper so that their cross section in the upper parts is smaller than the cross section near the lower part of the wall .

 As shown in FIG. 5 and 6, in the case of cross sections according to FIG. 7-9, the pylons 28, 30 and 30a are made integrally with the inner part 60 of the lower wall, as well as with the outer part 62 of the lower wall. The inner part of the lower wall or panel 60 and the outer part of the lower wall or panel 62 are combined to provide a double wall structure for the cellular container 20, while they are appropriately adjacent to the inner and outer surfaces of the pylons. The upper parts 86 of the lower parts of the wall smoothly connect the inner part 60 of the lower wall with the outer part 62 of the lower wall. This design ensures that the cellular packaging 20 will have sufficient strength and rigidity in various situations that arise during loading and unloading operations. As best seen in FIG. 3, 5, 6 and 15, the corner pylons 28 have the same dimensions, but are oriented differently depending on their location. Moreover, there are two sizes of the side pylons: the side pylons 30 located along the side walls 25 and in the center of the end wall 27 are of the same size, but the side pylons 30a, which are located on the end walls 27 between the central pylon and the corner pylons, have slightly increased dimensions. The difference is explained by the fact that since for uniformly stacking containers with four rows of bottles in six rows of six bottles in a row, a cellular container should have a width to length ratio of 2: 3, approximately one and a half distances occupied by the wall in the width direction should Be occupied with a cellular container in the length direction. In a honeycomb container according to the invention, this distance is provided in a preferred way — by increasing the thickness of the pylons 30a along the end wall 27. This configuration gives the honeycomb 20 additional strength, and also does not prevent the formation of numerous packages to facilitate automatic loading and loading and unloading operations.

 The views of the cellular containers in the profile according to FIG. 1, 2, 5 and 6 show that the outer part 62 of the bottom wall is preferably not completely flush with the bottom bottom surface 48, so that the surface 48 in profile remains somewhat exposed. When the outer part 62 of the lower wall remains slightly higher than the lower surface 48 of the bottom, loading and unloading operations are facilitated, since the introduction of a handcart under the cellular container is facilitated and the outer part of the lower wall is not trapped on the upper parts of the bottles when the container slides along the upper parts of the bottles as described above. The periphery of the bottom bottom surface 48 is performed with a beveled edge 49. In addition, the lower surfaces of the circles 52 and arcs 54 are the lowest points of the bottom surface 48 of the bottom. In FIG. 1, 3 and 4-6, they are collectively designated as the lower surface 53. The edges of the lower surface 53 are made with beveled surfaces 55. Therefore, when the honeycomb container 20 is resting on a flat surface, the lower surface 53 is in contact with the flat surface. Slopes 49 and 55 facilitate the handling of cellular containers.

 As best seen in FIG. 4, the lower wall portion 26 also has an open bottom so that the empty cellular packaging can be inserted into each other. A part of two tare inserted into each other is shown in detail in FIG. 15. For clarity, the lower mesh packaging is described below using the “prim” mark, for example, the upper mesh packaging 20 is mounted on or lower than the lower packaging 20. For the corresponding elements, positions with the "prim" icon will be used.

 Many advantages of the invention relate to the ability to insert cellular containers into each other. An assessment of structural features that facilitate the installation of containers in each other can be made with reference to FIG. 5, 6 and 15. When the empty cellular containers 20 and 20 'are inserted into each other, the pylons 28, 30 and 30a of the upper packaging 20 are mounted on or above the corresponding pylons 28', 30 'and 30a' of the lower packaging 20 ', so that pylons 28 ', 30' and 30a 'actually move upward inside the pylons 28, 30 and 30a, respectively. The side pylons 30 and 30a are located between adjacent supporting regions 34 (or 35, which is possible) and define spaces or windows 63 between them. In this case, when the cellular packaging 20 is loaded with bottles that are seated on the supporting zones 34 and 35, the sides of the bottles visible through windows 63 for demonstration in order to attract attention to them, especially when they are for sale.

 Preferably, the corner pylons 28 have openings 64 located on their inner surface to provide sufficient clearance for insertion or entry of the lower corner pylons. As best seen in FIG. 14, an opening 64 in the corner pylon 28 extends to the floor 22, where the corner support region 35 is also configured with a cutout 66 so as to provide free space for the lower approaching corner pylon. The upper inner parts of the corner pylons 28 include corner panels 65 that extend downward from the upper parts of the corner pylons to the openings 64. The central panels 70 form the lower surfaces 75 that are best seen in FIG. 4. In the joints between the upper part of the pylons 28 and the corner panels 65, slots 31 are formed.

 Similarly, the side pylons 30 and 30a are configured to provide sufficient clearance for the lower side pylons to fit into them. The inner sides of the side pylons 30 and 30a also have openings 68, but instead of remaining open, the integral central panel 70 having the upper part 72 and the lower part 74 extends down to the floor 22. The central panels 70 preferably extend under outward from the floor towards the top of the pylons and connect the pylons to the floor. Moreover, when the cellular packaging 20 is loaded with bottles, the Central panel 70 will partially pass between adjacent bottles. In the joints between the upper part of the pylons 30 and 30a and the upper parts 72 of the panels, slots 31 are formed.

 To control the degree of movement, at least two types of force stops are preferably formed on the inside of the pylons. The stops are formed in order to prevent jamming of the cellular containers inserted into each other, as well as to prevent any damage or deformation of the pylons, or the wall structure when re-inserting containers into each other and to maintain the weight of the containers inserted from above. The first stopper is located on the inside of the hollow pylons, and the second stopper is located on their outside. Outside the stoppers of the 76 pylons are box-shaped structures integrally formed with them located on the lower panel parts 74 of the side pylons 30 and 30a. The stops 76 extend vertically upward from the bottom 22, and the upper edges 78 of the stopper act as abutment surfaces for the panel bottom surfaces 75 when the cellular containers 20 and 20 ′ are inserted into each other. Although any number of panel bottom surfaces 75 can properly rest on the edges 78 'of the container inserted from the bottom, in a preferred embodiment, contact occurs on four side pylons located on the side walls 25 immediately adjacent to the corner pylons 28. For example, as shown in FIG. 15, the panel bottom surface 75 of the upper mesh container 20 is located slightly above the edge 78 'of the stopper 76' of the lower mesh container 20 'when the two containers are inserted into each other. Besides the fact that the stopper 76 serves to force the stopper when inserting the containers into each other, it also increases the strength of the central panel 70, which connects the pylons to the bottom. Preferably, stoppers 76 are provided on all side pylons 30 and 30a, however, the present invention is not limited to this configuration, and stoppers 76 can be formed on fewer pylons. At the junction with the stoppers 76, there are ribs 79 that extend upward from the upper edges 78 and are integral with the central panels 70. The ribs 79 help increase the strength of the central pylon panels.

 The stops on the inside of the pylons or the connecting ribs 80 are integrally formed in hollow spaces within the pylons 28, 30 and 30a. The connecting ribs 80 are best seen in cross section in FIG. 5, 6 and 15, moreover, in the cellular container 20 shown in FIG. 15, an exemplary connecting rib 80 is indicated by a dashed line. The ribs 80 are preferably located in the upper part of the pylons 28, 30 and 30a and are hidden by the corner panels 65 of the corner pylons 28 and the upper panel parts 72 of the side pylons 30 and 30a. Figure 4 shows in the best way how the ribs 80 advantageously overlap the inside of the pylons 28, 30 and 30a, connecting their inner and outer surfaces. When the cellular containers are inserted into each other, the ribs 80 rest on the upper parts of the pylons 28, 30 and 30a. Referring to FIG. 15, the ribs 80 of the honeycomb container 20 rest on the upper parts of the pylons 28 ′, 30 ′ and 30a ′ of the lower honeycomb container 20 ′.

 The dual structure of the lower wall portion 26 also contributes to another advantageous design feature — the grip parts 82, preferably centered on the end walls 27. As described above, the central pylons 30 along the end walls 27 are narrower than the other pylons 30a; this configuration also allows the handle parts 82 to be enlarged. The handle parts 82 are molded integrally on the outer lower part 62 of the end wall so that the user's hands extend into the space between the inner lower part 60 and the outer lower part 62 of the wall. When the honeycomb container 20 is gripped by the handle portion 82, the outer lower wall portion 62 provides a comfortable, smooth abutment surface for the wearer's hands.

 According to the invention, an additional distinguishing feature is provided, comprising a flat label portion 84 formed as part of the outer lower wall portion 62 for forming logical symbols, advertisements, and the like.

 The cellular packaging according to the invention combines the distinctive features of the ability to insert containers into each other, in their strength and visibility. When designing containers, many design parameters must be determined in order to increase the above characteristics without unduly degrading any of them. The ability to review is important both in order to provide an attention-grabbing demonstration and to ensure that labels on the sides of the bottles can be read or viewed through window 63 without having to remove the bottles. Improving the visibility of bottles, i.e. increasing the windows 63 between the pylons means reducing the size of the pylons, which leads to an overall decrease in strength. In addition, large windows increase the likelihood of popping bottles out of cellular containers through these windows. The present invention provides maximum visibility for its size without compromising strength and the ability to insert containers into each other.

 In addition, the ability to insert containers into each other is an important hallmark for saving space and ease of loading and unloading. The height that the honeycomb container adds to the stack of containers inserted into each other is called the increment from the insert. In the first embodiment, the increment from the insert is preferably about 1.5 inches (about 4 cm) for mesh containers whose total height is 3.95 inches (10 cm). The insertion coefficient is calculated by dividing the height by the increment, in this example 3.95 / 1.5 = 2.63. Consequently, the pylons extend approximately 2.5 inches (6.5 cm) above the lower wall portion and approximately 2.9 inches (7.5 cm) from the center. Obviously, the larger the insertion coefficient or the smaller the increment from the insertion, the more space can be saved. However, with regard to other design parameters, a simple increase in the coefficient of design parameters, then a simple increase in the insertion coefficient leads to other consequences. With an increase in the insertion coefficient, the strength and integrity of the cellular packaging decreases, since along with other adjustments the lower part of the wall must be reduced, due to which the required strength and stiffness are reduced.

The preferred side wall size in the first embodiment of the honeycomb container 20 is approximately 18.9 inches (48.2 cm) and the end wall is approximately 12.6 inches (32 cm). As mentioned above, the height of the described honeycomb containers is approximately 3.9 inches (about 10 cm), however, the height of the containers depends on the contour of the bottles, since some containers require a deeper container to hold. The thickness of the side pylons 30 in their upper parts is approximately 0.4 inches (about 1 cm), while the large pylons 30a have a thickness in the upper parts of approximately 0.6 inches (about 1.5 cm). Side pylons extend at an angle towards the inside of the honeycomb container, with the outside of the pylons extending upward from the outer lower part of the wall at an angle of approximately 5.7 ^° and meeting the actual upper surfaces of the pylons. The central panels extend outward from the floor in an upward direction at an angle of approximately 9.2 ^° from the vertical, meeting the flat upper surfaces of the pylons. The corner pylons extend at an angle to the inside of the honeycomb container, with the outside of the corner pylons extending upward from the outer bottom of the wall at an angle of about 5.7 ^° from the vertical to meet the flat upper surfaces of the corner pylons. The corner panel is actually vertical. The windows are formed by the lateral sides of the pylons, which extend at an angle of approximately 8 ^° from the vertical, so that the windows gradually expand towards the top of the pylons. Obviously, the dimensions of other preferred embodiments of the design will vary.

 The dimensions and angles described above are characteristic of the preferred embodiment of the invention and provide an optimal balance of the ability to insert containers into each other, strength and visibility. Of course, if necessary, adjustments can be made in the case of bottles or tanks having different contours or sizes, while the present invention is in no way limited to the above sizes.

 Other embodiments of containers according to the invention are described below using the same positions for the corresponding elements, but with the addition of different hundreds.

 As already discussed above, to obtain a cellular container, the capacity of which differs from the container capacity 20, the exact number of reference zones can be changed. In addition, as already discussed, in order to retain larger or smaller reservoirs, the proportions of sizes can be increased or decreased. The following description relates to additional embodiments of the construction of cellular containers.

 A second preferred embodiment of the invention is shown in FIG. 16 in the form of a cellular container 220. The container 220 is preferably designed to hold one liter bottles B arranged in three rows of four in each row. A size adjustment has been made, but the remaining distinguishing features of the cellular packaging 20 have been preserved.

 Similarly, a third preferred embodiment of the invention is shown in FIG. 17 in the form of a cellular container 320. The container 320 is designed to hold one-liter bottles B, arranged in three rows of five pieces in each row.

 A fourth preferred embodiment of the invention is shown in FIG. 18 in the form of a cellular container 420. The container 420 is also designed to hold one liter bottles B arranged in three rows of five pieces in each row.

 The main difference between the cellular containers 220, 320, 420 and the container 20 is the design of the handle part. The handle parts 282, 382 and 482, respectively, for honeycomb containers 220, 320 and 420 are a triple wall structure and can best be explained with reference to FIG. 19. To facilitate clarification, item numbers related to honeycomb containers 220 will be used, however it is obvious that containers 320 and 420 have corresponding distinguishing features regarding the handle portion.

 The handle portion 282 of FIG. 19 contains a zone in the form of a wall, while its part, the most spaced outward, is made integrally with the outer lower part 262 of the wall, and the part most spaced inward is made integrally with the inner lower part 260 of the wall.

 The outer part 262 of the end walls 227 is further away from the inner part 260, therefore, at the end walls, the lower part 226 of the wall is more massive. In these embodiments, the outer lower portion 262 at the end walls 227 is not adjacent to the outer lateral sides of the pylons 230, as was the case with the cellular container 20. The middle wall 283 is integrally formed between the outer portion 262 and the inner portion 260, and abuts against the outer sides pylons 230. The middle wall 283 is connected to the outer part 262 by means of a connecting element 285, which is preferably spaced some distance above the bottom surface 248 of the floor, but is located below the upper surface 286 of the lower part 226 of the wall. In this case, the cavity 287 of the handle part is formed between the middle wall 283 and the inner part 260.

 When using the grip part 282, it provides the ability to capture both “palm up” and “palm down”. When constructing the cellular packaging 420, cutouts 488 are made on the outside of the pylons 430 so as to provide more space for the user's hands when gripping the handle portion.

 From the above detailed description it is clear that the invention may include many changes, alterations and modifications that are obvious to qualified specialists in this field. However, it is assumed that such options do not deviate from the essence of the invention and are in its scope, which is determined solely by the attached claims.

Claims (20)

 1. A cellular container for tanks, containing the bottom and the wall structure, made in one piece with the bottom, while the bottom has upper and lower surfaces, and on the upper surface of the bottom there are a large number of support areas for holding tanks located in a row, and the wall structure made in one piece with the bottom and passes around its periphery, characterized in that it includes the lower part of the wall adjacent to the bottom and made in one piece with it, while the said lower part of the wall is a double the structure includes an inner lower part and an external lower part connected by an upper surface, a large number of tapering pylons extending upward from the bottom and beyond the upper part of said lower part of the wall, while said pylons are spaced apart from each other along the bottom periphery and form gaps through which tanks loaded into said cellular containers are visible, the inner surfaces of the pylons being made integrally with the inner lower part of the wall, and the outer surfaces of the pylons and one with the outer bottom of the wall.  2. The cellular packaging according to claim 1, characterized in that the said pylons extend at an angle to the inside of the cellular packaging and are hollow at least in their lower part to enable the pylons to be inserted into the corresponding pylons of another similar cellular packaging located below.  3. The cellular packaging according to claim 2, characterized in that the said pylons contain corner pylons located in the corners of the cellular containers, while each of the corner pylons includes a corner hole, side pylons located along the sides of the cellular containers, each of the side pylons includes an opening for allowing the pylons to be inserted into each other and a central panel extending downward from the top of the side pylon to be integral with the bottom, the central panel intersecting said opening started for inserting the pylons into each other, while said angular openings and holes for insertion provide sufficient clearance for said angular pylons to fit the corresponding angular pylons, and for said side pylons to fit the corresponding side pylons of another similar cellular packaging.  4. The cellular container according to claim 3, characterized in that it further comprises a locking means for restricting inward movement of the lower pylons inserted into the corresponding pylons located on top, to prevent jamming of the cellular containers inserted into each other.  5. The cellular container according to claim 4, characterized in that said locking means comprises connecting ribs in the upper parts of a certain number of said pylons, so that when the pylons are inserted into each other, the connecting ribs of the cellular packaging rest on the upper parts of the corresponding pylons of another similar cellular packaging below.  6. The cellular container according to claim 5, characterized in that said stopper means further comprises a certain number of said side pylons having a stopper on their central panel, so that when the cellular container is inserted under another same container, each said stopper provides an insertion edge on which the bottom surface of said central panel of the corresponding pylon of another detailed cellular container rests.  7. The cellular container according to claim 6, characterized in that the bottom surface of the floor includes a large number of recessed receiving zones for entering the upper parts of the tanks loaded into another similar cellular container located below, in order to maintain a stable configuration of the loaded cellular containers when stacked or cross stacked.  8. The cellular container according to claim 7, characterized in that the periphery of each of the said receiving zones is beveled to facilitate uncoupling of the upper parts of the tanks from the receiving zones.  9. The cellular container according to claim 8, characterized in that the said receiving zones include at least two receiving parts, each receiving part being designed to engage with the upper parts of the tanks having different sizes.  10. The cellular packaging according to claim 9, characterized in that the bottom surface of the bottom extends slightly below said outer lower part of the wall.  11. The cellular container of claim 10, characterized in that the said lower part of the wall includes handle parts made in one piece with it.  12. A cellular container for reservoirs having a bottom and a wall structure made in one piece with the bottom, while the bottom has an upper surface and a lower surface, and on the upper surface of the bottom there are a large number of support zones for holding tanks in a row, and the design the wall is made integrally with the bottom and passes around its periphery, characterized in that it includes the lower part of the wall adjacent to the bottom and made in one piece with it, while the lower part of the wall is a double the design and includes the inner lower part and the external lower part, a lot of tapering pylons extending upward from the bottom of the floor and beyond the upper part of the lower part of the wall, while the pylons are spaced from each other along the periphery of the bottom and form spaces between which are visible reservoirs loaded into the cellular container, the inner surfaces of the pylons made in one piece with the inner lower part of the wall, and the outer surfaces of the pylons made in one piece with the outer lower part of the wall, while the pylons odyat at an angle to the inner side of the mesh container and are hollow at least in its lower portion to permit insertion into the corresponding pylons pylons other such empty containers located underneath.  13. The cellular container according to claim 12, characterized in that it further comprises a locking means for restricting inward movement of the lower pylons inserted into the corresponding pylons located above, to prevent jamming of the cellular containers inserted into each other.  14. The cellular packaging according to item 13, wherein the locking means comprises connecting ribs in the upper parts of a certain number of pylons, so that when the pylons are inserted into each other, the connecting ribs of the cellular packaging are resting on the upper parts of the corresponding pylons of another similar cellular packaging located below.  15. The cellular container according to 14, characterized in that the said pylons contain corner pylons located in the corners of the cellular containers, each of the corner pylons includes a corner hole, side pylons located along the sides of the cellular containers, each of the side pylons includes an opening for allowing the pylons to be inserted into each other and a central panel extending downward from the upper part of the side pylon to be integral with the bottom, the central panel intersecting said opening significant for inserting the pylons into one another, wherein said corner openings and holes for insertion provide sufficient clearance for said corner pylons to fit corresponding corner pylons, and for said side pylons to fit corresponding pylons of another similar cellular packaging.  16. The honeycomb container according to claim 15, wherein said stopper means further comprises a certain number of said side pylons having a stopper on the central panel, so that when the honeycomb containers are inserted into another similar container, each stopper provides an insertion edge which rests the lower surface of the said central panel of the corresponding pylon of another similar cellular packaging.  17. The cellular container according to claim 16, characterized in that the bottom surface of the bottom includes a plurality of recessed receiving zones for receiving the upper parts of the tanks loaded into another similar cellular container located below, in order to maintain a stable design of the loaded cellular containers when stacking or cross-stacking, with the periphery of each of the receiving zones beveled to facilitate disengagement of the upper parts of the tanks from the said receiving zones.  18. The cellular container according to claim 17, characterized in that said receiving zones include at least two receiving parts, each receiving part being designed to engage with the upper parts of tanks having different sizes.  19. The cellular container according to claim 18, characterized in that the lower surface of the bottom extends slightly below said outer lower part of the wall.  20. A cellular container according to claim 12, characterized in that the lower surface of the bottom extends slightly below said external lower part of the wall.

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