US3244274A - Container for and filled with elongated tetrahedron packages - Google Patents

Container for and filled with elongated tetrahedron packages Download PDF

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Publication number
US3244274A
US3244274A US195823A US19582362A US3244274A US 3244274 A US3244274 A US 3244274A US 195823 A US195823 A US 195823A US 19582362 A US19582362 A US 19582362A US 3244274 A US3244274 A US 3244274A
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container
tetrahedron
packages
layer
tetrahedrons
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US195823A
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Wasyluka Paul
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Tetra Pak Inc
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Hermorion Ltd
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Priority to US195823A priority Critical patent/US3244274A/en
Priority to GB18444/63A priority patent/GB974585A/en
Priority to DE19631486707 priority patent/DE1486707B1/en
Priority to DK229663AA priority patent/DK136112B/en
Priority to CH622963A priority patent/CH417460A/en
Priority to ES288114A priority patent/ES288114A1/en
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Assigned to BRIK PAK, INC. reassignment BRIK PAK, INC. ASSIGNMENT OF ASSIGNORS INTEREST. Assignors: HERMORION LIMITED
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65DCONTAINERS FOR STORAGE OR TRANSPORT OF ARTICLES OR MATERIALS, e.g. BAGS, BARRELS, BOTTLES, BOXES, CANS, CARTONS, CRATES, DRUMS, JARS, TANKS, HOPPERS, FORWARDING CONTAINERS; ACCESSORIES, CLOSURES, OR FITTINGS THEREFOR; PACKAGING ELEMENTS; PACKAGES
    • B65D85/00Containers, packaging elements or packages, specially adapted for particular articles or materials
    • B65D85/54Containers, packaging elements or packages, specially adapted for particular articles or materials for articles of special shape not otherwise provided for
    • B65D85/542Containers, packaging elements or packages, specially adapted for particular articles or materials for articles of special shape not otherwise provided for for tetrahedral packages

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  • This invention relates to containers for and filled with a plurality of packages having the configuration of a tetrahedron and it is the general object of the invention to provide a new and improved construction which makes it possible to provide a container having a simple four-sided prismatic configuration which has a square cross-section, this container holding a plurality of layers of tetrahedron packages, each layer of which is constituted by a compact arrangement of four tetrahedrons, and the several layers being superimposed each upon the other, to the end of filling the interior of the 'containerwith a minimum loss of unstable space, thereby not only making it possible to use a simply configured container but also to establish an extremely efiicient packing factor for a package of this somewhat unusual configuration.
  • the novel container and packages packed therein are constituted by an elongated container having a four-sided prismatic configuration and which is square in transverse section, the packages being substantially congruent and constituted by elongatedt'etrahedrons each of which is defined by four substantially congruent isosceles triangular sides and having two opposite end edges substantially perpendicular to each other, each two triangular tetrahedron sides meeting respectively along each of said opposite edges at an included angle of about To establish an optimum filling factor in the container, each side of the square.
  • defining the transverse sec tion of the container has a length approximately 1.6 times the length of each of the two opposite tetrahedron edges, and the quotient of the length of each said tetrahedron edge divided by the distance between such edges is preferably from about .75 to .85.
  • Containers for and filled with tetrahedron packages are not broadly new, reference being made in particular to US. Patent No. 2,919,800 granted January 5, 1960 to Harry S. V. Jarund, but container structure according to this patent is of more complex configuration and involves use of packages having a regular tetrahedron configuration only. It cannot be used to eificiently stack or pack tetrahedrons which are elongated as distinguished from regular, i.e. in an elongated tetrahedron, the triangular sides would be isosceles triangles whereas in a regular tetrahedron, the triangular sides would be equilateral triangles.
  • the bottom wall of the container is also required to be at least a truncated portion of a substantially regular pyramid having six sides coordinated respectively to the six sides. of the container which is hexagonal in transverse cross-section as compared with a more simple flat bottom wall for a four-sided container in accordance with the present invention.
  • FIG. 1 is a view in side elevation of an elongated tetrahedron package which is to be stacked, or packed in a container according to the invention
  • FIG. 2 is a top plan view of the container showing one layer of four tetrahedron packages and illustrating the stacking pattern involved;
  • FIG. 3 is a perspective view of the container shown in FIG. 2 having a bottom layer of elongated tetrahedron packages stacked therein.
  • the tetrahedron package 1 illustrated in FIG. 1 is of the kind which is produced from a length of a tubular flexible packaging material by fiat-pressing and sealing transversely the ends of the tube length along narrow end zones to form two end sealing fins 2, 3 substantially perpendicular to each other.
  • the body of the tetrahedron package is constituted by four substantially congruent isosceles triangular sides 4.
  • the base edges of two opposite triangular sides meet along the inner line of one sealing fin 2 at an included angle of about 45 and the base edges of the other two opposite triangular sides meet along the inner line of the other sealing fin 3 also at an included angle of about 45".
  • package 1 which may be a liquid such as milk
  • theshape of the package body may depart slightly from a true geometrical tetrahedron, the package walls bulging slightly outwards as seen on the drawing.
  • the distance H between the inner lines of the two end. sealing fins 2, 3 is greater than the length B of the end seals, i.e. greater than the length of the base of each of the four triangular sides of the tetrahedron. More about this will be said later in the description.
  • FIGS. 2 and 3 show a container in which a bottom layer of four elongated tetrahedron packages each as illustrated in FIG. 1, are stacked or packed in accordance with the invention.
  • This container comprises a square fiat bottom wall 5 and four side walls 6, 7, 8 and 9-extending upwardly from the bottom Wall, these sidewalls defining substantially a straight prism of square transverse section.
  • the bottom layer comprises two oppositely directed, overlapping tetrahedron pairs 1a, 1b and 1c, M respectively, all of which rest upon the bottom wall 5.
  • the two tetrahedron packages In and 1b, and 1c, 1d are aligned and symmetrical to a diagonal plane indicated at 10, common to both pairs, passing through the longitudinal axis and diagonally opposite corners of the container, and engage each other in such plane 10.
  • sides of the tetrahedron packages of each pair opposite to the plane 9 engage adjacent side walls of the container.
  • the sides of one pair of tetrahedron packages 1a, lb engage adjacent container side walls 6 and 7, while the sides of the other pair of tetrahedron packages 1c, 1d engage the other adjacent container side walls 8 and 9.
  • Each pair of tetrahedron packages 1a, 1b and 1c, 1d, respec tively, is thus accommodated in a wedge-like manner in an individual one of two diagonally opposite inner side wall corners of the container, the upright one of the two mutually perpendicular edges of each tetrahedron package of each pair extending substantially along the adjacent container side wall corner edge.
  • the tetrahedron edge angle along this upright edge being substantially 45 as previously described, each pair of tetrahedron packages will have a snug wedge fit in the inner side wall corner of the container which encloses an angle of i.e. about twice the tetrahedron edge angle.
  • each one of the two tetrahedron packages of each pair 1a, 1b and 1c, 1a which constitute the bottom layer in the container will be firmly supported by the bottom wall 5 of the container and the adjacent side walls as well as by the other tetrahedron package of that pair.
  • the tetrahedron edge angle, or rather the quotient of the tetrahedron edge length B and the spacing H between end seals 2, 3 may vary somewhat yet ensuring a satisfactory stacking of packages in accordance with the invention. In practice, it is preferred to establish the value of the aforesaid quotient between limits of .75 and .85. When determining this dimensional relationship, as well as others which are to be later discussed, sealing zones or above-mentioned type have been taken into consideration. These sealing fins project from the body of the tetrahedron package and are an inevitable result in most methods of producing tetrahedron packages.
  • the two oppositely directed pairs of tetrahedron packages of the bottom layer are placed within the container in overlapping relationship.
  • one pair 1a, 1b rests in part on the other pair 10, id but one tetrahedron package of a first pair might as well rest in overlapping relationship upon that tetrahedron package of the second pair situated on the same side of said diagonal plane 1% common to both pairs, the other tetrahedron package of the second pair resting in overlapping relationship upon the other tetrahedron package of the first pair.
  • the sec-nd layer to be inserted in the container in accordance with the stacking pattern of the invention will also comprise two oppositely directed, overlapping pairs of tetrahedron packages.
  • the pairs of tetrahedron packages of the second layer will rest upon the upwardly facing triangular sides of the tetrahedron packages of the bottom layer, and in each such pair the two tetrahedron packages will be aligned and symmetrical to a diagonal plane 11 common to both pairs through the other diagonally opposite corners and longitudinal axis of the container, the plane 11 thus being perpendicular to the symmetry plane it) associated with the bottom layer of four tetrahedron packages.
  • the two tetrahedron packages of each pair which constitute the second layer will engage each other in the second diagonal plane Hand triangular sides of the packages opposite from the diagonal plane 11 will engage adjacent side walls of the container.
  • the general stacking configuration of the second layer of tetrahedron packages will be generally the same as that of the bottom layer of packages, the only dilference being that the respective planes of symmetry lit and 11 are perpendicular to one another.
  • the third layer will have the same orientation as the bottom layer, i.e. its plane of symmetry will coincide with plane 1th of the bottom layer.
  • Any fourth layer will have the same orientation as the second layer, its plane of symmetry coinciding with the symmetry plane 11 of the second layer.
  • the stacking pattern according to the invention has the feature that each layer of four tetrahedron packages has the same general stacking configuration, and that the various layers are placed each upon the other in such manner that the planes of symmetry of successive layers are alternately one and the other of two diagonal planes through the corners and longitudinal axis of the container.
  • the two overlapping tetrahedron pairs of superimposed layers having coinciding planes of symmetry i.e. layers one, three and five, or layers two, four and six, etc. have alternatively one or the other of two overlapping arrangements.
  • two tetrahedron packages adjacent one side wall corner of the container may partly overlie the other pair, while in the next succeeding layer, that tetrahedron pair adjacent the same side wall corner of the container may underlie the other tetrahedron pair of the latter layer.
  • the overlapping arrangement of equipositioned layers may alternate similarly, so that each tetrahedron of one layer overlies or underlies another tetrahedron of that layer, while the corresponding tetrahedron of the second next layer underlies, or overlies, respectively, the corresponding other tetrahedron thereof.
  • the width A of one side of the squarely configured container should exceed the distance H previously referred to in order to permit insertion of the tetrahedron packages 1 in the container in the improved stacking pattern.
  • Optimum stacking results have been obtained by dimensioning of the container in such a way as to yield a transverse container si-de width A equal to 1.6 times the length B of the base of each triangular side of the tetrahedron.
  • Table 1 Number Container Number of layers of tetraheight L in hadrons length B 4 1X13 8 1 3X13 12 2 3 B 16 2 6X13 20 3 6X13 24 3 9X13 From the above Table 1 it will be apparent that a container having stacked therein multiples of two layers in accordance with the invention will have its interior volume or capacity well utilized. However, for practical reasons, it is preferred that the number of layers of four tetrahedrons each should not exceed four for the reason that use of a greater number of layers will result in a container whose height L will be excessively great as compared with the dimensions of its squarely configured bottom wall.
  • a package for and filled with tetrahedron packages as defined in claim 1, comprising a multiple of tWo further layers of said tetrahedrons, the two pairs of tetrahedrons of each of said further layers being disposed similarly to those of said bottom layer and said second layer, said diagonal planes through the container axis alternating for successive layers.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Stackable Containers (AREA)
  • Package Closures (AREA)
  • Packages (AREA)
  • Making Paper Articles (AREA)

Description

GES
INVENTOR ATTORNEYS April 5, 1966 P. WASYLUKA CONTAINER FOR AND FILLED WITH ELONGATED TE'TRAHEDRON PACKA Filed May 18, 1962 F lg. 2
,1," IIIIIIIII'I'II' IIII'III'IIIIIIIIIII Paul WasyZu/(a.
United States Patent 0,
3,244,274 CGNTAINER FOR AND FILLED WITH ELGN- GATE!) TETRAHEDRON PACKAGES Paul Wasyluka, St. Louis, Mo., assignor to Hernrorion Ltd, Toronto, Ontario, Canada, a Dominion company of France FiledMay 18, 1962, Ser. No. 195,823 4' Claims. (Cl. 206-65) This invention relates to containers for and filled with a plurality of packages having the configuration of a tetrahedron and it is the general object of the invention to provide a new and improved construction which makes it possible to provide a container having a simple four-sided prismatic configuration which has a square cross-section, this container holding a plurality of layers of tetrahedron packages, each layer of which is constituted by a compact arrangement of four tetrahedrons, and the several layers being superimposed each upon the other, to the end of filling the interior of the 'containerwith a minimum loss of unstable space, thereby not only making it possible to use a simply configured container but also to establish an extremely efiicient packing factor for a package of this somewhat unusual configuration.
More particularly, the novel container and packages packed therein are constituted by an elongated container having a four-sided prismatic configuration and which is square in transverse section, the packages being substantially congruent and constituted by elongatedt'etrahedrons each of which is defined by four substantially congruent isosceles triangular sides and having two opposite end edges substantially perpendicular to each other, each two triangular tetrahedron sides meeting respectively along each of said opposite edges at an included angle of about To establish an optimum filling factor in the container, each side of the square. defining the transverse sec tion of the container has a length approximately 1.6 times the length of each of the two opposite tetrahedron edges, and the quotient of the length of each said tetrahedron edge divided by the distance between such edges is preferably from about .75 to .85.
Containers for and filled with tetrahedron packages are not broadly new, reference being made in particular to US. Patent No. 2,919,800 granted January 5, 1960 to Harry S. V. Jarund, but container structure according to this patent is of more complex configuration and involves use of packages having a regular tetrahedron configuration only. It cannot be used to eificiently stack or pack tetrahedrons which are elongated as distinguished from regular, i.e. in an elongated tetrahedron, the triangular sides would be isosceles triangles whereas in a regular tetrahedron, the triangular sides would be equilateral triangles. In the Jarund patent, the bottom wall of the container is also required to be at least a truncated portion of a substantially regular pyramid having six sides coordinated respectively to the six sides. of the container which is hexagonal in transverse cross-section as compared with a more simple flat bottom wall for a four-sided container in accordance with the present invention.
The invention will hereinafter be described more in detail with reference to the accompanying drawing which, by way of example, rather than in a limiting sense, illustrates anembodiment of the container and packages therein in accordance with the invention and which is defined more particularly in the appended claims. In the drawing:
FIG. 1 is a view in side elevation of an elongated tetrahedron package which is to be stacked, or packed in a container according to the invention;
FIG. 2 is a top plan view of the container showing one layer of four tetrahedron packages and illustrating the stacking pattern involved; and
ice
FIG. 3 is a perspective view of the container shown in FIG. 2 having a bottom layer of elongated tetrahedron packages stacked therein.
With reference now to the drawings, the tetrahedron package 1 illustrated in FIG. 1 is of the kind which is produced from a length of a tubular flexible packaging material by fiat-pressing and sealing transversely the ends of the tube length along narrow end zones to form two end sealing fins 2, 3 substantially perpendicular to each other. The body of the tetrahedron package is constituted by four substantially congruent isosceles triangular sides 4. The base edges of two opposite triangular sides meet along the inner line of one sealing fin 2 at an included angle of about 45 and the base edges of the other two opposite triangular sides meet along the inner line of the other sealing fin 3 also at an included angle of about 45". Due to the contents of package 1 which may be a liquid such as milk, and also because of the inherent flexibility of the package walls, theshape of the package body may depart slightly from a true geometrical tetrahedron, the package walls bulging slightly outwards as seen on the drawing. As indicated in FIG. 1, the distance H between the inner lines of the two end. sealing fins 2, 3 is greater than the length B of the end seals, i.e. greater than the length of the base of each of the four triangular sides of the tetrahedron. More about this will be said later in the description.
Referring now to FIGS. 2 and 3, these two views show a container in which a bottom layer of four elongated tetrahedron packages each as illustrated in FIG. 1, are stacked or packed in accordance with the invention. This container comprises a square fiat bottom wall 5 and four side walls 6, 7, 8 and 9-extending upwardly from the bottom Wall, these sidewalls defining substantially a straight prism of square transverse section. In the container, the bottom layer comprises two oppositely directed, overlapping tetrahedron pairs 1a, 1b and 1c, M respectively, all of which rest upon the bottom wall 5.
In each such pair, thetwo tetrahedron packages In and 1b, and 1c, 1d are aligned and symmetrical to a diagonal plane indicated at 10, common to both pairs, passing through the longitudinal axis and diagonally opposite corners of the container, and engage each other in such plane 10. Moreover, sides of the tetrahedron packages of each pair opposite to the plane 9 engage adjacent side walls of the container. Thus, the sides of one pair of tetrahedron packages 1a, lb engage adjacent container side walls 6 and 7, while the sides of the other pair of tetrahedron packages 1c, 1d engage the other adjacent container side walls 8 and 9. Each pair of tetrahedron packages 1a, 1b and 1c, 1d, respec tively, is thus accommodated in a wedge-like manner in an individual one of two diagonally opposite inner side wall corners of the container, the upright one of the two mutually perpendicular edges of each tetrahedron package of each pair extending substantially along the adjacent container side wall corner edge. The tetrahedron edge angle along this upright edge being substantially 45 as previously described, each pair of tetrahedron packages will have a snug wedge fit in the inner side wall corner of the container which encloses an angle of i.e. about twice the tetrahedron edge angle. Hence, each one of the two tetrahedron packages of each pair 1a, 1b and 1c, 1a which constitute the bottom layer in the container will be firmly supported by the bottom wall 5 of the container and the adjacent side walls as well as by the other tetrahedron package of that pair.
Dependent upon the flexibility of the package wall material and the nature of the package contents and/or the degree of filling, the tetrahedron edge angle, or rather the quotient of the tetrahedron edge length B and the spacing H between end seals 2, 3 may vary somewhat yet ensuring a satisfactory stacking of packages in accordance with the invention. In practice, it is preferred to establish the value of the aforesaid quotient between limits of .75 and .85. When determining this dimensional relationship, as well as others which are to be later discussed, sealing zones or above-mentioned type have been taken into consideration. These sealing fins project from the body of the tetrahedron package and are an inevitable result in most methods of producing tetrahedron packages.
As is apparent from the drawing, the two oppositely directed pairs of tetrahedron packages of the bottom layer are placed within the container in overlapping relationship. Preferably, one pair 1a, 1b rests in part on the other pair 10, id but one tetrahedron package of a first pair might as well rest in overlapping relationship upon that tetrahedron package of the second pair situated on the same side of said diagonal plane 1% common to both pairs, the other tetrahedron package of the second pair resting in overlapping relationship upon the other tetrahedron package of the first pair.
As with the bottom layer of tetrahedron packages in the container, the sec-nd layer to be inserted in the container in accordance with the stacking pattern of the invention will also comprise two oppositely directed, overlapping pairs of tetrahedron packages. The pairs of tetrahedron packages of the second layer will rest upon the upwardly facing triangular sides of the tetrahedron packages of the bottom layer, and in each such pair the two tetrahedron packages will be aligned and symmetrical to a diagonal plane 11 common to both pairs through the other diagonally opposite corners and longitudinal axis of the container, the plane 11 thus being perpendicular to the symmetry plane it) associated with the bottom layer of four tetrahedron packages. The two tetrahedron packages of each pair which constitute the second layer, like those packages of the bottom layer, thus will engage each other in the second diagonal plane Hand triangular sides of the packages opposite from the diagonal plane 11 will engage adjacent side walls of the container. Hence the general stacking configuration of the second layer of tetrahedron packages will be generally the same as that of the bottom layer of packages, the only dilference being that the respective planes of symmetry lit and 11 are perpendicular to one another.
If the container is to hold still a third, fourth or even more layers, the third layer will have the same orientation as the bottom layer, i.e. its plane of symmetry will coincide with plane 1th of the bottom layer. Any fourth layer will have the same orientation as the second layer, its plane of symmetry coinciding with the symmetry plane 11 of the second layer. Hence the stacking pattern according to the invention has the feature that each layer of four tetrahedron packages has the same general stacking configuration, and that the various layers are placed each upon the other in such manner that the planes of symmetry of successive layers are alternately one and the other of two diagonal planes through the corners and longitudinal axis of the container.
In order to obtain the closest possible stacking, i.e. to obtain the optimum filling factor for the interior volume of the container, it is preferred that the two overlapping tetrahedron pairs of superimposed layers having coinciding planes of symmetry, i.e. layers one, three and five, or layers two, four and six, etc. have alternatively one or the other of two overlapping arrangements. Thus, according to one arrangement, in one layer, two tetrahedron packages adjacent one side wall corner of the container may partly overlie the other pair, while in the next succeeding layer, that tetrahedron pair adjacent the same side wall corner of the container may underlie the other tetrahedron pair of the latter layer. According to the other and alternative arrangement, with respect to the tetrahedron pairs of fins 2, 3 of the one layer, the overlapping arrangement of equipositioned layers may alternate similarly, so that each tetrahedron of one layer overlies or underlies another tetrahedron of that layer, while the corresponding tetrahedron of the second next layer underlies, or overlies, respectively, the corresponding other tetrahedron thereof.
In accordance with the invention, the width A of one side of the squarely configured container should exceed the distance H previously referred to in order to permit insertion of the tetrahedron packages 1 in the container in the improved stacking pattern. Optimum stacking results have been obtained by dimensioning of the container in such a way as to yield a transverse container si-de width A equal to 1.6 times the length B of the base of each triangular side of the tetrahedron.
In practice, an even number of tetrahedron layers according to the present stacking pattern will yield the most advantageous use of the interior volume of the container. This is best illustrated in the following Table l which lists the container height L for various numbers of layers, the height L belng expressed in terms of the length B.
Table 1 Number Container Number of layers of tetraheight L in hadrons length B 4 1X13 8 1 3X13 12 2 3 B 16 2 6X13 20 3 6X13 24 3 9X13 From the above Table 1 it will be apparent that a container having stacked therein multiples of two layers in accordance with the invention will have its interior volume or capacity well utilized. However, for practical reasons, it is preferred that the number of layers of four tetrahedrons each should not exceed four for the reason that use of a greater number of layers will result in a container whose height L will be excessively great as compared with the dimensions of its squarely configured bottom wall.
I claim:
1. A container for and filled with congruent packages in the form of elongated tetrahedrons each defined by four substantially congruent isosceles triangular sides and having two opposite edges substantially perpendicular to each other, the two triangular tetrahedron sides meeting along each of said opposite'edges enclosing an edge angle of about 45, said container comprising a bottom wall and four side walls connecting thereto and arranged so as substantially to define a straight prism the cross section of which is a square having a side approximately 1.6 times the length of each of said two opposite tetrahedron edges, a bottom layer of two oppositely directed overlapping pairs of said tetrahedrons resting upon said container bottom wall and a second layer of two oppositely directed overlapping pairs of said tetrahedrons supported upon said bottom layer, the two tetrahedrons of each such pair of said bottom layer being symmetrical to one diagonal plane common to both pairs of the layer through the container axis and engaging each other in said plane while each by a triangular tetrahedron side opposite thereto engages an individual one of two adjacent container side walls, said two pairs of tetrahcdrons of said second layer being similarly disposed with respect to the other diagonal plane through the container axis as well as to the container side walls.
2. A package for and filled with tetrahedron packages as defined in claim 1, wherein the quotient of the length of each of said two opposite tetrahedron edges and their distance apart is from about .75 to .85.
3. A package for and filled with tetrahedron packages as defined in claim 1, comprising a multiple of tWo further layers of said tetrahedrons, the two pairs of tetrahedrons of each of said further layers being disposed similarly to those of said bottom layer and said second layer, said diagonal planes through the container axis alternating for successive layers.
4. A package for and filled with tetrahedron packages as defined in claim 1 wherein, in each layer of tetrahedrons, one tetrahedron of one of said pairs in overlapping relationship rests upon that tetrahedron of the other pair situated on the same side of said diagonal plane common References Cited by the Examiner UNITED STATES PATENTS 1,809,600 6/1931 Palmer 20665 X 2,887,221 5/1959 Woodward 206-65 2,919,800 1/1960 J'arund '206-65 JOSEPH R. LECLAIR, Primary Examiner. FRANKLIN T. GARRETT, Examiner.

Claims (1)

1. A CONTAINER FOR AND FILLED WITH CONGRUENT PACKAGES IN THE FORM OF ELONGATED TETRAHEDRONS EACH DEFINED BY FOUR SUBSTANTIALLY CONGRUENT ISOCELES TRIANGULAR SIDE AND HAVING TWO OPPOSITE EDGES SUBSTANTIALLY PERPENDICULAR TO EACH OTHER, THE TWO TRIANGULAR TETRAHEDRON SIDES MEETING ALONG EACH OF SAID OPPOSITE EDGES ENCLOSING AN EDGE ANGLE OF ABOUT 45*, SAID CONTAINER COMPRISING A BOTTOM WALL AND FOUR SIDE WALLS CONNECTING THERETO AND ARRANGED SO AS SUBSTANTIALLY TO DEFINE A STRAIGHT PRISM THE CROSS SECTION OF WHICH IS A SQUARE HAVING A SIDE APPROXIMATELY 1.6 TIMES THE LENGTH OF EACH OF SAID TWO OPOSITE TETRAHEDRON EDGES, A BOTTOM LAYER OF TWO OPPOSITELY DIRECTED OVERLAPPING PAIRS OF SAID TETRAHEDRONS RESTING UPON SAID CONTAINER BOTTOM WALL AND A SECOND LAYER OF TWO OPPOSITELY DIRECTED OVERLAPPING PAIRS OF SAID TETRAHEDRONS SUPPORTED UPON SAID BOTTOM LAYER, THE TWO TETRAHEDRONS OF EACH SUCH PAIR OF SAID BOTTOM LAYER BEING SYMMETRICAL TO ONE DIAGONAL
US195823A 1962-05-18 1962-05-18 Container for and filled with elongated tetrahedron packages Expired - Lifetime US3244274A (en)

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Application Number Priority Date Filing Date Title
US195823A US3244274A (en) 1962-05-18 1962-05-18 Container for and filled with elongated tetrahedron packages
GB18444/63A GB974585A (en) 1962-05-18 1963-05-09 Improvements in and relating to containers or holders housing tetrahedral packages
DE19631486707 DE1486707B1 (en) 1962-05-18 1963-05-14 Container for tetrahedral packs
DK229663AA DK136112B (en) 1962-05-18 1963-05-15 Packaging containing a number of tetrahedral containers.
CH622963A CH417460A (en) 1962-05-18 1963-05-17 Containers of polygonal cross-section with packages stacked therein
ES288114A ES288114A1 (en) 1962-05-18 1963-05-17 Improvements introduced in the manufacture of containers (Machine-translation by Google Translate, not legally binding)

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US195823A US3244274A (en) 1962-05-18 1962-05-18 Container for and filled with elongated tetrahedron packages

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CH (1) CH417460A (en)
DE (1) DE1486707B1 (en)
DK (1) DK136112B (en)
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GB (1) GB974585A (en)

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US3294232A (en) * 1965-05-10 1966-12-27 Tetra Pak Ab Compact stacking assembly for tetraiiedral packages in a container
US3303929A (en) * 1965-05-19 1967-02-14 St Regis Paper Co Multiple container package
US3734388A (en) * 1972-03-08 1973-05-22 A Hopkins Opening means for tetrahedral container
US3791570A (en) * 1972-09-15 1974-02-12 A Hopkins Opening means for containers
US20160090232A1 (en) * 2013-04-23 2016-03-31 Tetra Laval Holdings & Finance S.A. Distribution of tetrahedral packages

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NL1002991C2 (en) * 1996-05-02 1997-11-06 Barneveld Deelneming En Manage Packing method of sweets

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US1809600A (en) * 1929-07-09 1931-06-09 Palmer Henry William Samuel Packing sealed containers containing milk or other substances
US2887221A (en) * 1957-03-14 1959-05-19 Alton Box Board Co Clothes package
US2919800A (en) * 1951-04-10 1960-01-05 Jarund Harry Sigurd Valdemar Containers for tetrahedron shaped packages

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CH186414A (en) * 1934-11-22 1936-09-15 Limited Utility Cartons Liquid-tight container.
CH246680A (en) * 1944-06-29 1947-01-31 Emile Piquerez & Fils Flexible material container, obtained from a tubular element.
US2905316A (en) * 1957-09-23 1959-09-22 Mead Atlanta Paper Company Light bulb carton and overwrap therefor
DE1848861U (en) * 1961-11-27 1962-03-22 Bielefelder Papier Und Wellpap WEARING OR PACKAGING BOX.

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US1809600A (en) * 1929-07-09 1931-06-09 Palmer Henry William Samuel Packing sealed containers containing milk or other substances
US2919800A (en) * 1951-04-10 1960-01-05 Jarund Harry Sigurd Valdemar Containers for tetrahedron shaped packages
US2887221A (en) * 1957-03-14 1959-05-19 Alton Box Board Co Clothes package

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3294232A (en) * 1965-05-10 1966-12-27 Tetra Pak Ab Compact stacking assembly for tetraiiedral packages in a container
US3303929A (en) * 1965-05-19 1967-02-14 St Regis Paper Co Multiple container package
US3734388A (en) * 1972-03-08 1973-05-22 A Hopkins Opening means for tetrahedral container
US3791570A (en) * 1972-09-15 1974-02-12 A Hopkins Opening means for containers
US20160090232A1 (en) * 2013-04-23 2016-03-31 Tetra Laval Holdings & Finance S.A. Distribution of tetrahedral packages
US10029847B2 (en) * 2013-04-23 2018-07-24 Tetra Laval Holdings & Finance S.A. Distribution of tetrahedral packages

Also Published As

Publication number Publication date
DE1486707B1 (en) 1972-02-03
DK136112B (en) 1977-08-15
ES288114A1 (en) 1963-11-01
GB974585A (en) 1964-11-04
CH417460A (en) 1966-07-15
DK136112C (en) 1978-01-23

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