DE202011109120U1 - Blank for an octobin container and such a container - Google Patents

Abstract

Blank for an octobine container, which has a base area (10) delimited by a pair of longitudinal edges (10a, 10b) and a pair of transverse edges (10c, 10c) with eight side surfaces of one in the erected state, delimited from one another by folding lines (12a-12g) Has the body of an octobine container produced from the blank (1) forming partial surfaces (11a-11h), a first half (9a) of the blank (1) formed by four partial surfaces (11a-11d) and one by four further partial surfaces (11a- 11h), the second half (9b) of the blank (1) each have base elements (20a-20d or 20e-20h) which are arranged along the first longitudinal edge (10a) of the base area (10), in the erected state of the blank (1 ) form a bottom (110) of the octobine container and are movable via folding lines (21a-21h) with respect to the base surface (10) of the blank (1), the first and second partial surfaces (11a, 11b) around the second folding line (12b ) on the third and fourth sub-areas (11c, 11d) and the seventh and eighth sub-areas (11g, ...

Description

The invention relates to a blank for an octobinic container having a limited by a pair of longitudinal edges and a pair of transverse edges base surface with eight separated from each other by folding lines, erected side surfaces of a fuselage of an octobinic container manufactured from the blank forming partial surfaces, wherein a formed by four faces of the first half of the blank and formed by four further faces second half of the blank each have bottom elements which are arranged along the first longitudinal edge of the base, in the erected state of the blank forming a bottom of the octobinic container and folding lines against the base of the blank are movable, wherein the first and the second partial area about the second folding line on the third and fourth partial surface and the seventh and the eighth partial surface about the sixth folding line on the fün Fte and sixth partial surface are foldable such that the first partial surface over the fourth partial surface, the second partial surface over the third partial surface, the eighth partial surface over the fifth partial surface and the seventh partial surface over the sixth partial surface.

Such a blank for an octobinic container, such as a container erected from this blank, is known from US Pat DE 20 2010 010 886 U1 known. In the known blank, it is provided that each half of the blank has two bottom elements, which are arranged along the first longitudinal edge of the base of the blank and form the bottom of the octobinic container in the erected state of the blank. A first bottom element of each half of the blank has a fastening region and a second bottom element has a connecting region which can be folded around a folding line with respect to the remaining region of this second bottom element. The partial surfaces of each half of the blank associated with each of the first floor element are foldable around the folding lines adjoining them, together with their base element, to the partial surfaces associated with the second floor element of each half of the blank, so that in the folded state of the blank their connection area at the fastening area of cooperating with the respective second floor element first floor element can be fastened. The first floor element has a folding line, by means of which a first partial area of the first floor element is divided into a first partial area and a second partial area. The second subregion of the first subarea of the first base element can be folded together with the second subarea of the first base element about this folding line, so that in the folded state of the blank by flipping the second subarea including the second subarea of the first subarea about the first folding line Surfaces covered areas of the second floor elements are exposable. These are then applied with adhesive and bonded together. By means of an erecting movement of the blank folded in the radial direction, a movement of the first and the second bottom element in the axial direction of the container can be effected. As a result, an automatic bottom of erectable from the known blank container is formed, which allows a simple, even automated, setting up. The disadvantage of this is that under unfavorable circumstances there is a risk that the bottom elements will not overlap sufficiently in the event of faulty erecting of the blank to the finished container, so that no closed bottom is formed.

From the DE 201 13 798 is a blank as well as a prepared from the cut oktobiner container known. In the case of the octobinic container erected from the known blank, the bottom of the container is formed integrally with the base of the blank forming the body of the container. This has the advantage that in the production of the octobin tank it is no longer necessary to produce a separate blank for a hull and the bottom, erect the two blanks separately and then connect the erected blanks together. As a result, the manufacturing cost of the known container can be reduced and its erection simplified. A disadvantage of the known blank and the container erecting therefrom is that, for the final fixation of the bottom of the container, a fastening area of the first floor element must be glued manually or otherwise fixed together by a connecting person with a connecting area of the second floor element interacting therewith. This is particularly disadvantageous when a large number of containers from the known blanks must be erected.

The GB 1 196 422 A describes a blank for an octobinic container having point elements on which a bottom of an erected from this state octobinic container is formed. The disadvantage of this is that this is not automatable erectable from the straight blank. This also applies to the from the US 3,907,194 known blank.

It is an object of the present invention, a blank for an octobinic container of the type mentioned and such a container in such a way that from the blank according to the invention simply a container can be erected, with a closed bottom is formed with a high reliability.

This object is achieved in that the second bottom element movable about the second folding line relative to the second partial surface is connectable to the third bottom element movable about the third folding line relative to the third partial surface to form a first bottom region of the container which can be erected from the blank the first folding line relative to the first part surface movable first floor element is connected to the fourth bottom folding element relative to the fourth partial surface fourth floor element to form a second bottom region that the eighth sub-surface over the eighth folding line movable eighth floor element with the on the fifth folding line can be connected to the fifth partial surface movable fifth bottom element to form a third bottom region, that the over the sixth folding line relative to the sixth partial surface movable sixth bottom ement with the seventh folding line relative to the seventh part surface movable seventh floor element for forming a fourth floor area is connectable, and that an erecting movement of the thus folded base of the blank in the radial direction an erection movement of the bottom portions in the axial direction is effected.

The measures according to the invention have the advantage that in this way a blank is formed from which a container with an automatic floor can be erected in a simple manner. By now provided that all bottom elements of the blank according to the invention are connected to the erected in the erected state, the side surfaces of the hull part surfaces of the blank via folding lines, a high process reliability is given when erecting the container. By now providing that in each case two cooperating floor elements before the Aufrichtvorgang the blank according to the invention connected to the container according to the invention and thus four floor areas are formed, which collapse during the erection and overlap such, it is achieved that a closed floor in a reliable manner is trained.

Advantageous developments of the invention are the subject of the dependent claims.

Further advantages and details of the invention can be taken from the exemplary embodiment, which will be described below with reference to the figures. Show it:

1 : an embodiment of a blank for an octobinic container,

2 to 10 : a schematic representation of the erection process, and

11 : a representation of the bottom of the erected container.

In 1 is now a general with 1 designated embodiment of a blank for a octobin tank shown, which has a base 10 having, by longitudinal edges 10a . 10b and transverse edges 10c . 10d is limited. The base area 10 points eight, in the erected side surfaces of a fuselage of the blank 1 erected container forming part surfaces 11a - 11h which is essentially parallel to the transverse edges 10c . 10d running fold lines 12a - 12g are delimited from each other. To the first part surface 11a the base area 10 closes a fastener 11i which makes it possible, after successively folding the faces 11a - 11h around their folding lines 12a - 12g these have been formed into a closed hull surface of the container by attachment of the fastener 11i on the eighth section 11h the base area 10 of the blank 1 to fix in their closed form.

The cut 1 has eight floor elements 20a - 20h on, which along the first longitudinal edge 10a of the blank 10 arranged, preferably formed as integral parts thereof. The floor elements 20a - 20h are about folding lines 21a - 21h opposite the base 10 of the blank 1 movable. Like from the 1 can be seen, has both through the first four faces 11a - 11d trained first half 9a the base area 10 as well as one through the second four faces 11e - 11h trained second half 9b of the blank 1 four floor elements each 20a - 20d respectively. 20e - 20h on, which are contoured such that in the erected state of the blank 1 the floor elements 20a - 20h a floor 110 of the container (see 11 ) train. The floor elements 20a - 20d and the floor elements 20e - 20h the first and the second half 9a and 9b are here in functional terms mirror-symmetrical to the center line M of the base 10 forming folding line 21d arranged.

That about the first folding line 21a opposite the first part surface 11a of the blank 1 foldable first floor element 20a is divided into three subareas 20a ' . 20a '' and 20a ''' , The first and the second subarea 20a ' and 20a '' are through a first folding line 22a separated from each other, so that over the first folding line 22a the second subarea 20a '' and the one associated with it third subarea 20a ''' opposite the first subarea 20a ' of the first floor element 20a are foldable. The second and the third part 20a '' and 20a ''' of the first floor element 20a are through a second fold line 22a ' delimited from each other, with the two sub-areas 11a and 11b separating folding line 12a flees. The second part 20a '' and the third part 20a ''' are thus about the folding line 22a ' movable against each other and the first partial surface 11a can together with the sections 20a ' and 20a '' of the first floor element 20a relative to the third sub-area 20a ''' be moved in the Aufrichtvorgang described below. The first section 20a and the second subarea 20a '' own it - like out 1 apparent - together a width, which is substantially the width of the first partial surface 11a equivalent. The third section 20a '' of the first floor element 20a proceeds from the first and the second partial surface 11a and 11b separating folding line 12a in the presentation of the 1 obliquely upwards and thus projects into the - virtual - extension of the second partial surface 11b trained "floor area" into it. The width of the third section 20a ''' is less than that of the first subarea 20a ' and the second subarea 20a '' of the first floor element 20a trained area and the third section 20a ''' goes - as from the 1 is also apparent - stepwise in the second section 20a '' over, so here's a recess 24a is formed, whose function is based on the Aufrichtvorgangs the blank 1 to the octobin tank will be described. The first floor element 20a is through two transverse edges 23a ' and 23a '' as well as a longitudinal edge 23a '' limited, whose courses from the 1 is apparent. The exact course of the edges 23a ' - 23 '''' as well as that of the edges of the other bottom elements described below 20b - 20h then becomes the description of the folding process of the blank 1 explained.

The one around the eighth folding line 20h opposite the eighth partial surface 11h movable eighth floor element 20h is according to the first floor element 20a trained and will therefore not be described again.

The second floor element 20b is the second folding line 21b opposite the second partial surface 11b of the blank 1 movable and has a trapezoidal shape. It has two transverse edges 23b ' and 23b '' on top of the folding lines 12a and 12b go out and to a longitudinal edge 23b ''' run, which is substantially parallel to the longitudinal edge 10a of the blank 1 is.

The about the folding line 21g with the seventh partial area 11g of the blank 1 connected seventh floor element 20g is according to the second floor element 20b trained and is therefore not described in detail.

That about the third folding line 21c with the third part surface 11c of the blank 1 connected third floor element 20c has two parts 20c ' and 20c '' on that around a folding line 22c are movable against each other. A first transverse edge 23c is essentially in the extension of the second folding line 12b , a second transverse edge 23c '' starts from the third folding line 12c and runs in the representation of 1 diagonally to the top left. He goes to a longitudinal edge 23c ''' about, which is substantially parallel to the third folding line 21c of the third floor segment 20c runs. This is followed by a longitudinal edge 23c '''' on, the second part 20c '' of the third floor element 20c limited. This longitudinal edge 23c '''' rises in the presentation of the 1 starting from the longitudinal edge 23c ''' to the top left and then falls slightly to the first transverse edge 23c ' off, leaving the second subarea 20c ' of the third floor element 20c in the transverse direction of the blank 1 over the first section 20c ' protrudes.

That about the sixth folding line 21f with the sixth partial area 11f connected sixth floor element 20f is according to the third floor element 20c educated.

That about the fourth folding line 21d opposite the fourth partial surface 11d movable fourth floor element 20d has two faces 20d ' and 20d '' on, with the second partial area 20d '' opposite the first part surface 20d around a folding line 22d is foldable so that the second partial surface 20d '' - as described below - on the first surface 20d ' of the fourth floor element 20d can be handled. A second folding line 22d ' Aligns with the fold line 12c and serves that in the representation of the 1 To the left of her lying area of the first section 22d ' as well as the corresponding area of the second subarea 22d '' during Aufrichtvorgang as described below is movable. A first transverse edge 23d ' runs in the representation of 1 from the folding line 12c starting diagonally to the top left. A second transverse edge 23d '' Aligns with the fold line 12d the base area 10 of the blank 1 , He goes to a longitudinal edge 23d ''' over, who in the 1 has shown course.

The fifth floor element 20e which is via the fifth folding line 21e opposite the fifth partial surface 11e of the blank 1 is foldable, is corresponding to the fourth floor element 20d built up.

This erection process is now based on the 2 to 10 explains: The 2 shows again the cut of the 1 in an easy way perspective view. The two subareas 11a and 11b the first half 9a of the blank 1 become together with their floor elements 20a and 20b around the folding line 12b worked out, leaving the transverse edge 10c of the blank 1 is moved to the center line M. How out 3 can be seen, then lies the first part surface 11a the base area 10 of the blank 1 over the fourth partial area 11d and the second subarea 11b over the third part surface 11c , The first floor element 20a lies above the fourth floor element 20d and the second floor element 20b above the third floor element 20c ,

In a corresponding manner then the seventh and eighth partial area 11g and 11h along with their floor elements 20g and 20h around the sixth folding line 12f worked out, leaving the edge 10d is also moved to the center line M. The eighth partial area 11h then lies above the fifth subarea 11e and the seventh section 11g over the sixth partial area 11f , The eighth floor element 20h lies above the fifth floor element 20e and the seventh floor element 20g above the sixth floor element 20f , The edges 10c . 10d of the blank 1 lie above the center line M. To this closed form of the blank 1 to fix, then becomes the fastener 11i with the eighth partial area 11h connected.

Like now the 3 to 6 then becomes the second subarea 20a '' of the first floor element 20a including the third section 20a ''' folded up, by these subregions 20a '' and 20a ''' around the first folding line 22a to be moved. In a corresponding manner, the second subarea 22h '' and the third part 22h ''' of the eighth floor element 20h moved upwards by going around the eighth folding line 22h be folded up. This folding-up process can be carried out easily by a known packaging machine and then leads to the floor elements previously covered by the folded-up areas 20d respectively. 20e to expose, like this from the 4 is apparent.

Then the second subarea 20d '' of the fourth floor element 20d as well as the second subarea 20f '' of the sixth floor element 20e around the respective folding line 22d respectively. 22e inside, ie towards the interior of the blank 1 erected container, folded, so their in 1 invisible surfaces 26d respectively. 26e - like out 6 visible - in the illustration of these figures show upward. On these surfaces 26d . 26e Now it is easy to apply glue. These folded sections 20d '' and 20e '' form fasteners 28d and 28e which serve as described below the floor elements 20d respectively. 20e and the floor elements 20a respectively. 20h connect with each other to floor areas 110b respectively. 110c (please refer 9 ) train.

The two around the folding line 22a respectively. 22h movable sections 20a '' . 20a ''' respectively. 20h ' . 20h ''' the first and the eighth floor element 20a . 20h are folded back so that they are in contact with the adhesive coated fasteners 28d respectively. 28e to step. By gluing the sections 20a '' . 20a ''' of the first floor element 20a with the connecting element 28d of the fourth floor element 20d as well as the subareas 20h ' . 20h ''' of the eighth floor element 20h with the connecting element 28e of the fifth floor element 20e thus becomes a permanent connection between these floor elements 20a . 20d respectively. 20h . 20e made and thus the floor areas 110b and 110c of the soil.

After that - like the 4 to 6 show - the second section 20c '' of the third floor segment 20c around the folding line 22c on the second floor segment 20b worked out, so that in the 3 and 4 visible surface 26c of the second subarea 20c '' of the third floor segment 20c - how then out 6 apparent - on the surface of the second floor element 20b to come to rest. The second part 20c '' thus forms a connecting element 28c which serves to the third floor element 20c with the second floor element 20b to connect to it a floor area 110a form of the container. For this purpose, it is preferably provided that the surface 26c before being folded over with adhesive, so that then by folding over and pressing this connecting element 28c to the second floor element 20b a lasting connection is created. The same applies to the second subarea 20f '' of the sixth floor element 20f on the seventh floor element 20g of the blank 1 worked and connected to this permanently.

This second section 20f '' of the ground segment 20f thus forms a connecting element 28f out, so by folding it over on its surface 26f adhesive coated connector 28f and its pressing against the floor element 22g an area 1100d of the soil 110 is trained.

The in 8th plan lying presented blank 1 in the "pre-erected" form given by the above procedure is now ready for delivery to the end user. It is advantageous that the blank 1 is particularly flat, so it is characterized by low transport costs.

The erection process of the container from the blank 1 and in particular the automatic Forming the soil 110 will now be based on the 8th to 10 explained. By pulling the blank apart 1 in opposite directions X the ground forms 110 automatically off by interacting floor elements 20a - 20h cover. The radial movement of the part surfaces 11a - 11h trained hull of the container causes the floor elements 20a - 20h , caused by this radial Aufrichtbewegung, perform a movement in the axial direction of the container until a closed bottom 110 is formed, in which the floor elements 20a - 20h Cover accordingly. The floor 110 of the blank 1 erected container is divided into the four floor areas 110a - 110d , The in 9 left floor area 110a is through the interconnected as above floor elements 20b and 20c trained, just like the one in 9 right floor area 110d through the floor elements 20f and 20g is trained. The second floor area 110b becomes through the ground segments interconnected as described above 20a and 20d trained, as well as the third floor area 110c through the interconnected floor elements 20h and 20e is trained. The 9 shows the beginning of the erection process, in which the corresponding floor elements 20a - 20h by the radial pulling apart of the partial surfaces 11a - 11h not far from her in 8th shown plane position have moved in the axial direction, so that between the first and the second floor area 110a and 110b still a free space 111 , between the second and third floor area 110b and 110c still a free space 111b and between the third and fourth floor areas 110c and 110d still a free space 111c located.

By further pulling apart the faces 11a - 11h in the directions X the 9 then approach - as if from a comparison of 9 and 10 is apparent - the floor areas 110a and 110b respectively. 110c and 110d to each other, in which case the interconnected and together the floor area 110a forming ground segments 20b and 20c - like out 10 visible - over the floor elements 20a and 20d of the second floor area 110b slide. To make this possible, the third subarea must 20a ''' be configured so that its longitudinal edge 23 ''' for the formation of the recess 24a is configured such that the floor elements 20b and 20c sufficiently far above the floor elements 20a and 20d can be pushed that through the floor areas 110a and 110b a closed bottom is formed.

The same then applies to the floor areas 10c and 10d forming ground segments 20h and 20e and 20g and 20f , Like the same 10 can be seen, push in the righting movement of the ground segments 20a - 20h trained soil 110 of the container then these one above the other by the bottom elements 20h the floor element 20d and the floor element 20f the floor element 20e partially overlap. The floor 110 of the finished container is then in 11 shown.

In summary, it should be noted that by the described blank 1 a container with an automatically raised floor 110 can be formed, which is characterized in that each floor element 20a - 20h about his folding line 21a - 21h with its associated subarea 11a - 11h is connected, so that a high process reliability when erecting the container and in particular in the formation of the soil 110 given is. By now provided that two each have a floor area 111 - 111d forming ground segments 20b . 20c respectively. 20a . 20d respectively. 20h . 20e respectively. 20g . 20f each by a connecting element 20c '' respectively. 20d '' respectively. 20e '' respectively. 20f '' Being connected together, a high process reliability when erecting the soil 110 reached.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202010010886 U1 [0002]
• DE 20113798 [0003]
• GB 1196422 A [0004]
• US 3907194 [0004]

Claims (6)

Blank for an octobinic container, one through a pair of longitudinal edges ( 10a . 10b ) and a pair of transverse edges ( 10c . 10c ) limited area ( 10 ) with eight from each other by folding lines ( 12a - 12g ) demarcated, in the erected state side surfaces of a fuselage one of the blank ( 1 ) produced octobinen container forming surfaces ( 11a - 11h ), one by four faces ( 11a - 11d ) trained first half ( 9a ) of the blank ( 1 ) and one by four further faces ( 11a - 11h ) trained second half ( 9b ) of the blank ( 1 ) each floor elements ( 20a - 20d respectively. 20e - 20h ) along the first longitudinal edge ( 10a ) of the base area ( 10 ) are arranged, in the erected state of the blank ( 1 ) a floor ( 110 ) of the octobin container and via folding lines ( 21a - 21h ) compared to the base area ( 10 ) of the blank ( 1 ) are movable, wherein the first and the second partial surface ( 11a . 11b ) around the second folding line ( 12b ) on the third and fourth partial surface ( 11c . 11d ) and the seventh and the eighth partial area ( 11g . 11h ) around the sixth folding line ( 12f ) to the fifth and sixth partial area ( 11e . 11f ) are foldable such that the first partial surface ( 11a ) over the fourth partial area ( 11d ), the second subarea ( 11b ) over the third partial area ( 11c ), the eighth partial area ( 11h ) over the fifth partial area ( 11e ) and the seventh partial area ( 11g ) over the sixth partial area ( 11f ), characterized in that that around the second folding line ( 21b ) in relation to the second partial area ( 11b ) movable second floor element ( 20b ) with the one around the third folding line ( 21c ) in relation to the third partial area ( 11c ) movable third floor element ( 20c ) for forming a first floor area ( 110a ) of the blank ( 1 ) erectable container is connectable, that via the first folding line ( 21a ) in relation to the first partial area ( 11a ) movable first floor element ( 20a ) with the one around the fourth folding line ( 21d ) opposite the fourth partial surface ( 11d ) movable fourth floor element ( 20d ) for forming a second floor area ( 110b ) is connectable, that in relation to the eighth partial surface ( 11h ) via the eighth folding line ( 21h ) movable eighth floor element ( 20h ) with the via the fifth folding line ( 21e ) opposite the fifth sub-area ( 11e ) movable fifth floor element ( 20e ) for forming a third floor area ( 110c ) is connectable, that via the sixth folding line ( 21f ) in relation to the sixth partial area ( 11f ) movable sixth floor element ( 20f ) with the one around the seventh folding line ( 21g ) compared to the seventh partial area ( 11g ) movable seventh floor element ( 20g ) for forming a fourth floor area ( 110d ) is connectable, and that by an erecting movement of the thus folded base ( 10 ) of the blank ( 1 ) in the radial direction (X) an erection movement of the floor areas ( 110a - 110d ) in the axial direction is effected. Blank according to claim 1, characterized in that the third and the fourth floor element ( 20c ; 20d ) as well as the fifth and the sixth floor element ( 20e ; 20f ) each a connecting element ( 28c respectively. 28d respectively. 28e respectively. 28f ), via each of which two interacting floor elements ( 20b . 20c ; 20a . 20d ; 20h . 20e ; 20g . 20f ) for the formation of a respective floor area ( 110a ; 110b ; 110c ; 110d ) are connectable. Blank according to claim 2, characterized in that the third floor element ( 20c ) and the fifth floor element ( 20c ) each have a first subregion ( 20c '; 20f ' ) and a second subregion ( 20c '; 20f ' ) each having a folding line ( 22c ; 22f ) are movable relative to each other, and that the respective second subarea ( 20c ''; 20f '' ) of the corresponding floor element ( 20c ; 20f ) for forming the connecting element ( 28c ; 28f ) via the with the third and the fifth floor element ( 20c ; 20f ) cooperating second or sixth floor elements ( 20b ; 20g ) foldable and connectable with this. Blank according to claim 1, characterized in that the first floor element ( 20a ) and the eighth floor element ( 20h ) each have a first subregion ( 20a '; 20h ' ) and at least a second subregion ( 20a ''; 20h '' ), which are defined by a first or eighth folding line ( 22a ; 22h ) are movable relative to each other, and that the second subregion ( 20a ''; 20h '' ) in each case in such a way around its associated folding line ( 22a ; 22h ) is foldable, that thereby an area of the under the first or fifth floor element ( 20a ; 20h ) lying third and fifth floor element ( 20c ; 20f ) is exposable. Blank according to one of the preceding claims, characterized in that the fourth and the fifth floor element ( 20d ; 20e ) a first subregion ( 20d '; 20e ' ) and a second subregion ( 22d ''; 22e '' ) which in each case have a folding line ( 22d ; 22e ) are movable relative to each other, and that in each case the second subregion ( 20d ''; 20e '' ) for forming a connecting element ( 28c ; 28e ) to the first subarea ( 20d '; 20e ' ) is foldable. Octobin tank, with a hull and a floor ( 110 ), characterized in that the container is made of a blank ( 1 ) is designed according to one of claims 1 to 5.

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