 MACHINE AND METHOD FOR FORMING CARDBOARD BOXES FROM DIE-CUTTING FLAT SHEETS AND CARDBOARD BOX (Machi
专利摘要:
Machine and method of forming cardboard boxes from die-cut flat plates, and cardboard box. The machine (100) comprises a male (60) with the shape of an inverted truncated pyramid movable in a linear direction Z into a mold (50) with forming stops (56), movable between respective retracted and stop positions to evacuate boxes (B) of the mold (50) by an outlet mouth (55) opposite a plate inlet mouth (54), the forming stops (56) having concave curved surfaces (S2), complementary to convex curved surfaces (62a') with an inverted conical section shape located in four corner areas of the male (60); a conveyor with a rotational encoder (13) coupled to a rotary motor (12) configured together to move in a controlled manner a pusher member (16) of the plate (P) along linear guides (40); and pressurizable glue injectors (45) configured to deposit glue (CC) on the plate (P) during its transport. (Machine-translation by Google Translate, not legally binding) 公开号:ES2839552A2 申请号:ES202031091 申请日:2020-10-29 公开日:2021-07-05 发明作者:Olmos Telesforo Gonzalez 申请人:Telesforo Gonzalez Maquinaria SL; IPC主号:
专利说明:
[0004] TECHNICAL SECTOR [0006] The present invention presents a machine and a method for forming boxes from die-cut flat plates, optionally intended to be nested, and with a cardboard box capable of being obtained by said machine and method. [0008] The boxes, of preferential application in the food sector, are specifically made of cardboard, for example corrugated or compact, which provides rigidity and an advantageous reduced biodegradation time compared to plastic or metallic materials. [0010] BACKGROUND OF THE INVENTION AND TECHNICAL PROBLEM TO BE SOLVED [0012] The technical problem to be solved is the economic, simple and effective automation of the formation of cardboard boxes by means of a machine and a method with a high productive speed. It would be desirable to achieve speeds of several thousand or even tens of thousands of boxes formed per hour. [0014] Thus, the typical thermoformed plastic and metal tray-type boxes, usually used in the food sector in general, and the plastic ones in the fruit and vegetable sector in particular, can be replaced by cardboard trays, which have very advantageous time drastically less biodegradation. [0016] Document BE603605A reports a stamping tool and a method of forming trays from rigid aluminum sheets. The tool consists of a movable male and a blind mold, closed at the bottom by a bottom plate 4, on which are mounted corner-forming stops 15 with angular and rounded shape to form curved corners of the box. The corner formers can oscillate in a vertical diagonal plane of the die, with an inclination both in the retracted and stop position, so the formed boxes must be extracted again by the upper mouth of the mold, severely limiting their speed of production. [0018] As the BE603605A document itself indicates, the box corner folds remain stable thanks to the nature of aluminum. Also, the folds are thanks to the previous cooperation with the elements 15 of some fingers 19 of the mold, directed against each other equal distances with respect to the vertical diagonal plane of the elements 15 and adjacent to the corner area of the box. Disadvantageously, the use of the fingers 19 would tear and / or deform the cardboard undesirably, and more at the high speeds desired with the present invention. [0020] Document US2925758A shows a box forming machine from metal sheets or similar combinations, where the material, once folded, maintains its folded position. Such a machine is not suitable for the production of cardboard boxes, since metallic materials have memory before bending. [0022] Similarly, document US2014374472A1 explains that the technical solutions used to mold aluminum boxes cannot be used to mold cardboard boxes because cardboard is not as malleable and ductile as aluminum; if the cardboard is fed into an apparatus for molding aluminum boxes, the cardboard would tear and / or break, thus preventing the box from being obtained, similarly to BE603605A. [0024] Document US3305434A discloses a method for forming rigid cardboard boxes from a sheet moistened between 15 and 35% by weight, which is subsequently pressed between a core and a blind mold, designed to evacuate the vapors of the pressing water. Prior to positioning between the core and the mold, the plate of a desired diameter is produced from a cardboard reel. [0026] Document US3792809A reports a corrugated cardboard tray with selected regions provided with pre-cut lines, which are deformed by compression, between a movable male and a fixed blind mold, so as to ensure that the peripheral region of the tray will maintain a raised arrangement in the form of a continuous bent-out rail. V-shaped pre-cut lines 82 are made at the corners of the box in radial directions. The tray is formed in a single cutting and molding step from a continuous strip of cardboard by relative movement between the core and cutting elements 18 and 22 of the mold. [0028] Document US4609140A discloses a rigid carton, and an apparatus and method for the production thereof. The method comprises selecting a plate moistened between 8 and 12% by weight, and subsequently pressing it against a movable core and a blind mold heated between 121 and 160 ° C. To increase the pressure on the container edges, the surfaces of the core and mold are closer in those regions than those that define the bottom. Moisture weakens the bonds between cardboard fibers, facilitating the formation of the container. The fibers flow into the cardboard under pressure, causing wrinkle mitigation and other fault lines on the cardboard edge. When the core is out of the mold, the ridges are a substantially compact structure. The fold lines 20 of the flange of Fig. 1 and the surroundings of these are strongly compressed and glued so that these folds do not present natural folding lines or weakened lines, having a resistance similar to compact cardboard. [0030] Document US6093460A reports a square cardboard tray with curved corner areas, where linear creases 117 are formed by pressing the cardboard by means of a molding apparatus provided with a linearly movable core through a blind mold. The plate fed into the molding apparatus is pre-punched at a station external to the molding apparatus, whereby the tray is manufactured in sequential steps. [0032] Document US2014374472A1 refers to an apparatus and method for molding corrugated cardboard trays. The apparatus has a movable core and a fixed blind mold facing each other, where the cardboard strip C, without punching and previously moistened, is fed between the electrically heated core and mold to dry the cardboard during molding. Male and mold have cutting and counter-cutting blades, 18, 21, which cooperate to punch the plate during the linear movement of the male inside the mold. [0034] Disadvantageously, the cited documents have a low production speed of boxes, usually on the order of several hundred boxes formed per hour. [0036] Document ES2348810T3 discloses a method for manufacturing cardboard trays, comprising the steps of: cutting a flat plate by means of a laser beam making linear cuts 6 in the corner panels on the inner side of the plate (Fig. 1); hot stamping the previously cut plate, compressing it along the linear cuts 6, and double folding a plastic coating of the plate in the compressions 8 of the molding; and melting the plastic liner 9 in the compressions 8 keeping the tray 7 its shape. [0038] Documents EP0419068B1 and EP0608971A2 report tray formation methods, where the cardboard from reels is die cut, folded and preformed. Two cartons are inserted one into each opposite half of a mold from a blow molding machine. Vacuum holes in each half of the mold secure the position of each blank. The halves are closed by means of a "parison" (hot extruded element of malleable polymer), which is inflated inside the mold, by means of a needle that injects blown gas into the parison, expanding it towards the internal corners and cracks of the folded cardboard. After cooling, the mold halves are opened and the pair of trays are ejected. The trays formed have a base, four side walls facing each other in pairs, and flanges arising from the short side walls with end portions like bends for joining with the flange ends of the long side walls. [0039] In document EP0419068B1, the trays have corner areas with cone section originating from the long side walls 21, and ending in fixing tabs 25 that are adhesively bonded to the short side walls. The blank of Fig. 3 does not have crease or crease lines separating the larger side wall 21 from the corner areas, nor does it separate it from the fixing flange. [0041] In document EP0608971A2, the tray is made of corrugated cardboard and has chamfers 12, 14, 16, 18 in the corner areas, giving the tray an octagonal configuration. The long and short side walls have respective ridges 20 to 23 provided with kinks in correspondence with the chamfers. [0043] On the other hand, document US4522618A describes a machine with a mold, and an inverted truncated pyramid-shaped core that can be inserted linearly into the mold, to form boxes with four inclined side walls intended to be nested one inside the other, starting from a plate that is placed on some plate guides immediately above the mold. Before the male presses the plate, glue is applied to parts of the plate. The core then presses the plate against the mold, and mold pressure rollers resist the entry of the core and move out of the mold cavity as the core and plate move into the mold, moving the iron inside the mold. These rollers firmly engage parts of the sheet with glue against the outer surfaces and provide elastic pressure to squeeze and spread the glue and press the glue to form the box. The mold is not rigid, but the mold rollers can yield and follow the inverted truncated pyramid shape of the core. The plate, once pushed by the core through the mold, passes through a box outlet mouth and falls onto a conveyor. [0045] Document US4522618A proposes three alternatives for applying glue. In Figs. [0046] 1 to 3 and 5, the glue applicator slows down the productive speed of boxes, since it is an applicator support 120, 121 that raises finger-shaped rods 130 impregnated with glue from a tub of glue 125 to apply dots of glue on the iron. Alternatively, Fig. 9 shows signal activatable glue injectors, which are positioned just above the mold inlet mouth, and laterally outside the carton folding space. Document US4522618A itself indicates it is more precise and faster to achieve a high production volume, because it is not necessary to wait for a few drops of glue to fall from the rods. In another alternative, Figs. 10 to 12 propose two glue rollers 330 with respective embossed glue applicator surfaces 331 that coincide with respective glue strips 331A to be applied on the plate, inflexible to adapt to changing sizes or formats of boxes. [0047] In EP3305514B1, a box forming machine with eight side walls by folding and gluing die-cut plates comprises a mold with a cavity having a plate inlet mouth, and a box outlet mouth, and a driven male according to a linear direction Z by a drive between an extracted and inserted position in the cavity. Mold pressure blades are moved by blade actuators between retracted and pressure positions. Each single and compound wall bender in the mold has inlet and front bender surfaces parallel to the linear Z direction. In Fig. 3, the pairs of clamping blades are limited to pressing on four alternate sides, facing two by two, of the octagonal cavity. [0048] The glue applicator of document EP3305514B1 is located on a conveyor between a plate loader and the mold cavity, and comprises a plurality of elements for applying hot and cold glue on predefined areas of the plate as it is moved by the conveyor. [0050] None of the machines of documents US4522618A and EP3305514B1 are structurally and functionally equipped to form boxes intended to be nested with each other and neither to form curved corners in these boxes. [0052] Alternatively, machines provided with a rotary head with a plurality of heads mounted on the head can exhibit high forming speeds, but have disadvantages compared to machines of the male type that can be moved linearly through the mold cavity: high machine manufacturing cost. , excessive height and / or plant dimensions, and complex operation, adjustment, and maintenance. [0054] Documents GB1490301A and CA1121199A disclose respective methods and machines for the formation of trays from cardboard sheets intended to be nested with each other and provided with outer edges folded towards the outside of the box. [0056] Document GB1490301A proposes a male element and a mold facing each other, between which a plate is initially placed. The male inserts the plate into the mold through an upper mouth to bend some parts of the plate with others. The formed box is extracted again by the upper mouth by means of a lifting plate that moves the bottom of the box from the inserted position to a raised position on the mold. The mold is configured to only insert and extract boxes through its upper mouth since it is a blind bottom mold. To finish the extraction of the box, a device F transports the boxes individually from the raised position to a lateral position on another conveyor G. These folding and extraction operations are complex and slow, causing the plate to have a stopping point in the production cycle, stopping the plates fed to said mold and core. [0058] Another drawback of document GB1490301A is that the adhesive is obtained by blowing hot air over certain areas of a plate stopped in a position on a conveyor, melting the hot-melt coating to join some parts of the plate with others. This causes the plate to have a second slowdown in the continuous production cycle. [0060] Document CA1121199A is considered the closest state of the art, and proposes to position, on a mold and under a facing male, a plate with applied adhesive. The male in its introduction into the mold through the entrance mouth forms the bottom, the side walls and adheres the walls against the reinforcement flaps. The four flanges 25 and 27 located in the upper part of the side walls 19 and 21, are bent towards the outside of the box and joined to each other in overlapping portions by means of glue dots applied on the plate. When the male reaches the maximum insertion position the tray is nested with the previously formed trays forming a stack through a vertically aligned mold outlet mouth of the input mouth. [0062] A drawback of document CA1121199A is that the speed of the forming machine is restricted to the speed with which the tap oscillates between said maximum extraction and insertion positions of its Fig. 3, and precisely the tap must make a long vertical travel to be able to carry out all the folding operations of the box from its flat plate according to the vertical. In addition, the stack of nested boxes is also vertical and is located just below the mold. [0064] This long vertical path of document CA1121199A limits the speed of formation of the boxes, since with the core inserted into the long vertical cavity of the mold, no other plate can be positioned between the core and the mold to carry out the next bending cycle and expulsion. [0066] The long vertical travel of the male causes the height measurement of the machine to be excessive, implying problems in the transport and installation of said machine. [0068] Disadvantageously, the machines of documents CA1121199A and GB1490301A comprise an excessive number of elements of considerable measures, which add extra cost, complexity, and excessive machine height, increasing the unit cost of box formation. [0069] EXPLANATION OF THE INVENTION [0071] According to a first aspect, to overcome the above drawbacks, the present invention presents a machine for forming cardboard boxes intended to be nested, from previously punched flat plates. [0073] These boxes capable of being formed in such a machine are typically provided with a bottom and four lateral sides facing two by two surrounding the bottom, with respective convergent inclinations causing transverse and longitudinal measurements of the upper mouth of the box greater than the measurements of the bottom, to allow nesting of some boxes with others. These boxes have at least four box corner areas that separate two respective contiguous side sides. [0075] The box can be made of corrugated (corrugated) cardboard or alternatively compact cardboard, among others, which provide the box with a certain rigidity to simplify its machine formation. [0077] Preferably, the stamping of the plate is carried out on a stamping machine. The die-cut sheet obtained has cut lines and weakened fold lines. The fold lines can be crease and / or cut-crease lines, to facilitate the formation of the box by bending parts of the flat plate around them. [0078] The machine comprises a chassis, and a mold, a tap drive and a tap, supported therein. [0080] The mold comprises a cavity aligned with a core according to a linear Z direction, and an entrance mouth of the plate to the cavity and an exit mouth of the cavity formed from the cavity, aligned according to the linear Z direction. The exit mouth is sized to evacuate the formed boxes from the cavity through it. [0082] The male drive is configured to move the male guided in the linear direction Z in opposite directions, between positions of maximum extraction and insertion of the male with respect to the cavity. In the position of maximum extraction the male is outside the cavity, and in the position of maximum introduction the male is inside the cavity. [0084] The tap drive may comprise a mechanism of bars configured to transform the movement of a rotating electric motor into the linear movement of a bar; a fluid dynamic cylinder provided with a linearly guided movable rod or piston; a rack and pinion type mechanism coupled to a rotating electric motor, or a mechanism comprising a threaded rod driven by a rotating electric motor, among others. [0085] Throughout the description, the term "linear direction" preferably corresponds to the vertical direction, although the present invention also expressly includes the case where the linear direction corresponds to the horizontal direction. [0087] Said male is connected by means of a connection support to the male drive. The male is essentially in the shape of an inverted truncated pyramid, with four flat lateral sides arranged facing two by two around the connection bracket forming respective inclinations with respect to the linear Z direction, the four flat lateral sides defining four corner areas of the male, each one between two respective inclined flat lateral sides adjoining it. [0089] These inclinations with respect to the linear direction Z, allow to form boxes with inclined side walls with respective inclinations greater than 90 degrees with respect to the bottom of the box, so that some boxes formed within others can be nested. Illustratively, said inclinations can be between 92 and 105 degrees, thus each of the flat lateral sides of the core forming an inclination (angle) between 2 to 15 degrees with respect to the linear Z direction. [0091] The core comprises front and rear sides according to the direction of introduction of the core into the mold. The front side comprises a flat bottom surface integrated into the male configured to press a bottom portion of a flat plate positioned at the inlet mouth and insert it into the cavity. [0093] Up to this point, the characteristics and elements of the forming machine of the aforementioned document CA1121199A, considered as the closest to the state of the art, have been described. [0094] According to this first aspect, the present invention also proposes, in combination, in a way per se not known from the existing state of the art, the elements and characteristics that are listed below. [0096] In the machine, each corner zone of the core includes a convex curved surface in the shape of an inverted conical section, complementary to a respective curved concave surface of the mold. [0098] Herein, these concave and convex curved surfaces are understood to be inwardly curved (concave) or outwardly curved (convex), respectively. [0100] The mold further comprises a plurality of forming stops, mutually facing and arranged laterally around the cavity. [0102] Each of the shaping stops is movable between a retracted position, adjacent to the cavity, to enable the insertion of the flat plate to be formed in the cavity, and a stop position, towards the interior of the cavity. [0104] Each of the shaping stops is provided with at least one of said concave curved surfaces arranged laterally around the cavity, movable between said retracted and stop positions. [0106] The movable shaping stops are configured to evacuate the formed boxes from the cavity in the retracted position through the outlet mouth without interfering with the shaping stops. [0108] Among others, this invention expressly covers the following possibilities: a mold with two shaping stops, a mold with four shaping stops, a mold with eight shaping stops, where preferably in any of these options each stop is movable by one or more respective actuators stop. [0110] These movable concave curved surfaces are configured so that, in their stop positions and with the male in the position of maximum insertion, press the outer part of the box towards the inside of the cavity, this outer part including the four corner zones of the box, against the four convex curved surfaces of the male. [0112] Likewise, the machine also comprises a conveyor supported on the chassis, equipped with two linear guides, one on each side of the plate to be transported. [0114] The conveyor also comprises a rotary motor and a rotational encoder coupled to the rotary motor, configured together to controlly move a plate pusher member according to a linear transport direction X perpendicular to the linear direction Z, from an initial position to a position associated with the inlet mouth. [0116] Possible embodiments of this rotational motor and encoder are: a servomotor that integrates a rotary motor and an encoder, connected to a servomotor controller; a rotational encoder coupled to the electric rotary motor, in turn connected to a frequency variator; an electric motor in general coupled to a rotational encoder, among others. [0117] By "rotational encoder", it will be understood in this specification any detection device, in particular associated to the shaft of a rotating motor, that provides a response indicative of the rotary movement imparted by the motor, by means of an electrical signal that can be read by some type from control device into a motion control device, such as a "programmable logic controller" (PLC), a "microcontroller", a "controller", a "programmable automaton", "control system", "control unit ”," Logic controller programmable "," processor "," microprocessor "," computer "and" computer ", among others The term encoder includes the term encoder. [0119] Likewise, the machine further comprises a plurality of pressurizable glue injectors, preferably by means of a pressurized air device, and preferably heated by means of resistive heating means. These tail injectors are supported on the chassis and arranged transversely to the linear transport direction X. [0120] The glue injectors are configured to deposit dots or beads of glue on the plate during its transport as a function of the controlled position of the pusher member. [0121] The glue injectors are configured to join directly or indirectly by means of this glue four lateral sides of the box, facing two by two that surround the bottom of the same. [0123] Advantageously, the present invention proposes to use a machine with a mold in which the plates enter through an entrance mouth and the boxes formed exit through said exit mouth of the formed box, despite the mold including the forming stops provided with the curved surfaces. concaves, which are specially configured to, through their movement from the stop position to the retracted position, allow the evacuation of each box formed from the cavity passing through the exit mouth and not through the plate entrance mouth, causing an increase in the number of boxes produced in a given time interval by avoiding associated downtime and slow and complex cash evacuation operations. [0125] The concave and convex curved surfaces of the core and mold, respectively, press the corner areas of the box, thus being configured to obtain curved corner areas in the cartons by molding from the flat die-cut cardboard plate. [0126] Advantageously, the formation of the box at high speeds by means of this machine, and particularly through the configuration of the mold, occurs efficiently with the previously punched flat plate with or without lateral fold lines that separate corner panels that will form the curved corner areas and / or the side flaps of the side walls attached to the bottom of the box, simplifying the automated formation of such a box. [0128] These curved corner areas obtained can have an inverted conical section, allowing the use of standardized size molds for plastic boxes with curved corners with inverted conical section, widely used today, and associated with the subsequent thermo-sealing phase. from the top of the box. A) Yes, Advantageously, the integration of the automatic forming machine in the existing heat-sealing lines is simplified with minimal adaptations, in favor of a direct replacement. [0129] Advantageously, in the present invention, all the operations for forming the box from the flat sheet of cardboard (for example bending, pressing and pressure molding) can be carried out during the travel of the core towards the position of maximum insertion and the positioning of this in this position, thus increasing the speed of formation in a compact, inexpensive and simple machine. [0131] To enable this high formation speed, it is only necessary to optimize times in the area of the core and the mold, but also a suitable transport and union technology between parts of the plate for this purpose. [0133] For this, a joint configuration of the rotary motor and the rotational encoder is proposed, which allows to move in a controlled manner at high speeds a pusher member of the conveyor linearly aided by means of linear guides, in combination with a specific joining solution between part of the plate, specifically, by means of pressurizable, and optionally heated, glue injectors of the machine, which deposit the glue on the plate with precision and reliability even at high speeds, depending on the controlled position of the push member read by the rotational encoder. Said glue to be heated is optionally a hot melt glue, also called "hot-melt". [0135] Preferably, the machine lacks a device for moistening the blank, and lacks a device for heating the concave and / or convex curved surfaces. [0137] Optionally, these devices that the machine lacks are ones that are configured to provide humidity and heat substantially above the ambient humidity and temperature conditions where the machine is located, respectively. [0139] Differentially from the state of the art, the machine does not need these means of humidification and heating to mold the corner areas of the box with an inverted truncated pyramid section curved shape, which avoids cooling and drying times, thus obtaining a simple machine. , economical, efficient, and of relatively high production. [0141] Preferably, the concave curved surfaces are configured to lock in respective abutment positions. [0143] This immobilization confers rigidity to concave curved surfaces while they are exerting pressure in use against the outer part of the core in its stop position, which is very advantageous to make compatible a high productive speed with the creation of the plurality of well-defined essentially linear wrinkles in each corner zone of the box to obtain the curvature of these, via a suitable configuration to exert pressure between the concave and convex curved surfaces of the core and mold, respectively. [0145] The immobilization can correspond to a mechanical immobilization, for example, corresponding to the edges of the thread of a threaded rod or spindle; to immobilization by means of an electrical control and / or power signal associated with an actuator, for example, a brake of said rotary motor coupled to the encoder; to an immobilization of the axis of rotation of said rotary motor coupled to the encoder; to an immobilization of the movable part of a fluid dynamic cylinder in that position associated with the pressure and force of a fluid such as air or oil, among others. [0147] Optionally, each of the shaping stops is configured to move by one or more respective stop actuators. [0149] According to one embodiment, the mold comprises two shaping stops. Each of these two shaping stops comprises three lateral bearing surfaces: one corresponds to a lateral bearing face with an inclination with respect to the linear direction Z, complementary to the inclination of a respective flat lateral side, configured to press in the abutment position a side side of the box against that complementary flat side side; and two others correspond to two of said concave curved surfaces, arranged adjacently one on each side of the lateral end face. [0151] Complementary to the previous paragraph, each of the two shaping stops comprises five lateral support surfaces, with two other lateral support faces with respective inclinations with respect to the linear direction Z, complementary with inclinations of respective flat lateral sides, arranged adjacently one on each of said concave curved surfaces. [0153] Each of these two other side end faces is configured to press in the abutment position other respective opposite side sides of the box, against respective opposite flat side sides. [0155] Optionally, these five lateral end faces of each of the two shaping stops are configured to join by means of said pressure some lateral sides of the box with others, by means of points or beads of glue previously applied on preselected areas of the plate by the plurality of glue injectors. [0156] According to another embodiment, the mold of the machine comprises four shaping stops. Each of these four shaping stops comprises two lateral support surfaces: one corresponds to a lateral support face with an inclination with respect to the linear direction Z, complementary to the inclination of a respective flat lateral side, configured to press in the stop position a lateral side of the box against a flat lateral side of the male, and the other corresponds to said concave curved surface. [0157] According to another embodiment, the mold of the machine comprises four shaping stops. Each of these four shaping stops comprises three lateral flange surfaces: a concave curved surface, and two lateral flange faces with respective inclinations with respect to the linear Z direction, complementary with inclinations of respective flat lateral sides, flanking the concave curved surface. [0159] These three surfaces are configured to press in the stop position a corner area of the box and both side sides of the box bordering it, against a corner area of the core and portions of the flat side sides bordering it. [0161] According to another embodiment, in the machine, the mold comprises four auxiliary shaping stops, mutually facing each other in pairs and arranged laterally around the cavity. Also, the mold comprises four forming stops positioned at the respective corners of the cavity and alternately with the auxiliary forming stops. [0163] Each one of these auxiliary shaping stops is provided with at least one inclination lateral flange face complementary to that of a respective flat lateral face, this being at least one lateral flange face movable between a retracted position to enable the insertion of the flat plate to form in the cavity, and a stop position, towards the interior of the cavity. [0165] The movable auxiliary shaping stops are configured to evacuate the formed boxes from the cavity in the retracted position through the outlet mouth without interfering with the auxiliary shaping stops. [0167] Preferably, the shaping stops have integrated eight molding edges adjoining the respective ends of the concave curved surfaces and with respective inclinations with respect to the linear direction Z, configured to cooperate with respective male edges adjoining the respective ends of the convex curved surfaces. [0168] Optional core and molding edges allow for increased forming speed via efficient folding of the box side flaps, and the corner panels adjacent to these that form the corner zones. This bending occurs during movement of the forming stops from the retracted position to the stop position, without increasing the unit box formation time. [0170] Preferably, they are machined or fixedly coupled on blocks of nylon, preferably cast nylon, the side end surfaces that are optionally separated by respective molding edges of the forming stops, and the core corner areas that optionally include respective core edges. [0172] Advantageously, this achieves a precise and fast positioning of the bent and pressed parts of the plate, allowing to increase the forming speed without experiencing frequent production stops, and allowing a subsequent joining of some lastar walls with others through the side flaps with reliability. and speed. [0174] The precision lies in the easy machining of this material. Due to the possible lack of a heating device for the curved and / or convex surfaces in the machine, it is possible to use this nylon material without suffering heat deformation that would prevent the boxes from being obtained. [0176] Preferably, in the machine, each of said concave curved surfaces of the mold includes a respective pressure surface of dimensions essentially corresponding to each of the convex curved surfaces. Optionally, shaping edges of the shaping stops have an edge segment of essentially coincident length with a respective core edge. [0178] Complementarily to the previous paragraph, at least four of the mentioned lateral end faces are configured to maintain two different lateral separations with respect to the flat lateral sides of the male: a first separation in two mutually opposite flat lateral sides associated with the thickness of the plate, and a second separation on the other two mutually opposite flat lateral sides associated with twice the plate thickness. [0180] With this double separation, a tight coupling between the parts of the core and the mold is achieved to exert mutual pressure between both, and also to position without place in error the side walls and the curved corner areas of the box, even in view of optional subsequent operations of formation of the same. This efficient positioning enables reliable box forming while maintaining a high production speed. [0182] Preferably, the mold comprises two mutually facing presses, arranged laterally around the cavity. The presses are movable between a retracted position towards the outside of the cavity and a pressure position towards the inside of the cavity. The presses are configured to press into the pressure position the outside of the box on two opposite side sides of the box, against respective opposite flat side sides of the plug. [0184] With the presses, the aforementioned coupling is improved, which also occurs essentially around the entire lateral contour of the core, which comprises the four side walls and all the corner areas of the box. [0186] Preferably, plug, mold, and inlet and outlet ports are aligned with the linear direction Z along the vertical. The glue injectors are arranged suspended on the linear guides, which are horizontal along a transport direction X perpendicular to the vertical linear direction Z. Also, the mold is configured so that the boxes come out below the outlet mouth. [0188] This preferred embodiment proposes applying glue using a specific technology on the flat plate at a high speed thereof, thanks to the horizontal guidance of the plate and the suspended glue injectors that precisely deposit the glue even if the speed increases. [0190] Linked to the previous horizontal transport of the plate, this arrangement proposes a vertical displacement of the male, which clearly simplifies the extraction of the box formed through the outlet mouth, aided in any case by gravity. [0191] In both operations, application of glue and exit of formed box, the machine is configured to execute them without plate or box stops throughout the production cycle, increasing its speed. [0193] Preferably, each of the shaping stops includes an upper bearing face, configured to receive the pressure, with the male in the position of maximum introduction and with the shaping stops in the stop position, of flanges arranged on the upper part of the sides. sides of the box previously bent outwards by a male bender device mounted on the rear side. [0195] The male bender device comprises four paired facing forming members and four paired facing corner forming members. [0197] These eight forming members are arranged around the connection support and in use positioned protruding towards the outside of the male configured to bend said flanges outwards, each forming member being associated with a respective flat lateral side and each corner forming member positioned in a corner area of the core sandwiched between two contiguous forming members. [0199] The four angled forming members are configured to press, with the male positioned in the position of maximum introduction, superiorly by contacting some overlapping portions of the edges located in the corner areas of the box, and gluing these edges against each other by pressure and hot glue deposited by the glue injectors in these portions of overlap. [0201] Advantageously, the present invention is also compatible for its implementation for the formation of boxes intended to be nested, which are also provided with ridges located in the upper part of the lateral sides that surround the bottom of the box, being able to be open from the top of the box. Tray type to preferably facilitate the subsequent closure of the container by means of a film that seals the upper part open. [0203] According to a second aspect, to overcome the drawbacks set forth in the previous section, the present invention presents a method of forming cardboard boxes intended to be nested, from previously punched flat plates. These stamped plates can be obtained on a stamper machine. [0205] The method is carried out by means of a forming machine equipped with a mold with a cavity facing a male linearly movable through the cavity. [0207] Optionally, this method of the second aspect can be executed by the machine of the first aspect of the invention. [0209] The method comprises the following steps known in the state of the art: [0211] z) placing in the machine the aforementioned previously punched plate provided with cutting and folding lines; [0213] a) moving a core that is essentially in the shape of an inverted truncated pyramid, according to a linear Z direction, between positions of maximum extraction and insertion of the core with respect to the cavity; [0215] y) moving the plate according to a linear transport direction X perpendicular to the Z direction from an initial position to a position on an entrance mouth to the cavity; [0217] b) pressing by means of said male a bottom portion of the plate inserting it into said cavity; [0219] c) joining directly or indirectly some side walls of the box with others with dots or beads of glue deposited on the plate; [0221] e) after steps b) and c), bend at least two side walls attached to the bottom portion of the box to be formed by means of the mold in cooperation with respective flat lateral sides of the male distributed around the linear direction Z, and having these sides respective flat sides inclinations with respect to the linear direction Z; Y [0223] g) evacuating the boxes formed from the cavity by passing through an outlet mouth of the mold aligned in a linear direction Z with the inlet mouth. [0225] According to this second method aspect, the present invention further proposes, in combination, in a way per se not known from the existing state of the art, the steps and characteristics listed below. [0227] The method also comprises the steps of: [0229] h) moving a plurality of mold-shaping stops, each one provided with at least one concave curved surface in the shape of an inverted conical section arranged laterally around the cavity, from a retracted position, in order to be able to insert the plate to be formed into the cavity, up to a stop position towards the interior of the cavity; [0231] m) pressing by means of said concave curved surfaces, the outer part of the box including the four corner areas thereof, towards the interior of the cavity, against respective corner areas of the male, each of which includes a Inverted conical section-shaped convex curved surface complementary to a respective concave curved surface, each convex curved surface disposed between two contiguous inclined flat lateral sides of the core; [0233] x) molding each of the four box corner areas contiguous to two side walls of the box, creating a plurality of wrinkles essentially linear with each other in the box corner areas during steps h) and / or m), providing this plurality of wrinkles created an essentially curved surface in the shape of an inverted conical section in the box corner areas; [0235] k) moving the forming stops from their stop position to the retracted position to allow stage g) of evacuating boxes without interfering with the forming stops, after stages m) and x); [0237] w) moving a thrust member in a controlled manner according to the linear transport direction X, by means of a rotary motor and a rotational encoder coupled to the rotary motor, to move the plate of stage y) in a controlled manner; Y [0239] u) depositing dots or strands of glue, preferably hot, to carry out at least step c), this deposition being a function of the position of the push member according to the controlled movement of step w). [0241] With the present invention, the essentially curved shape of the box corner areas is achieved with the plurality of essentially linear wrinkles created by the convex and concave curved surfaces of core and mold, respectively. These wrinkles, by way of linear compressions, are laterally separated in pairs by a distance of the order of a few millimeters and / or even below a millimeter, thus defining and generating the essentially curved surface, preferably with an inverted conical section. [0243] The advantages described for the first aspect of the invention also apply to this method of the second aspect of the invention. [0245] In any case, the automated production of the box from a die-cut flat plate is simplified, which can optionally have a lower number of fold lines. [0246] Preferably, after stage z), the method lacks the steps of moistening the plate, and of heating the concave and / or convex curved surfaces to a working temperature, above the ambient humidity and temperature conditions where the plate is located. machine. [0248] Preferably, this working temperature corresponds to the temperature necessary to melt an adhesive, and preferably hot glue. [0250] Preferably, the method further comprises step 1) of immobilizing the concave curved surfaces of the shaping stops in their respective stop positions. [0252] Preferably, step m) further comprises pressing two opposite side walls attached to the bottom portion of the box against two mutually opposite flat lateral sides of the core, by means of two mutually opposite flat side mold faces and with respective inclinations with respect to the direction linear Z, movable between retracted and stop positions, and each one of them arranged between two concave curved surfaces. [0254] In a preferred option, the blank sheets from which the boxes are formed are of corrugated cardboard, the corrugated cardboard comprising at least one smooth sheet and a corrugated sheet provided with corrugated undulations, these sheets being adhered to each other. Furthermore, in molding step x), the plurality of essentially linear wrinkles are essentially parallel or perpendicular to the direction of the grooved undulations in the box corner areas. Thus, preferably, the concave and convex curved surfaces deform the corrugated structure of the corrugated cardboard along the linear wrinkles to create them. [0256] Preferably, the plurality of essentially linear wrinkles are essentially parallel to the direction of the fluted undulations. This arrangement of grooves Corrugated cardboard helps the generation of linear wrinkles and the formation of box corner areas with smoother curves. [0258] Preferably, molding step x) lacks the step of folding and overlapping portions of the corner area of the box so that in these portions the thickness of the lateral contour of the box is equal to or greater than three times the thickness of the previously die-cut plate. This triple thickness can be associated with Z-shaped folds. [0260] Preferably, the method further comprises the steps of: [0262] d) applying stitches or strands of hot glue on overlapping portions of outer flanges located in the upper part of the lateral sides of the formed box, to join the flanges with the others; [0264] f) bending the four flanges towards the outside of the box, by means of a male bending device mounted on a rear side of the male; [0266] i) receiving on the upper end faces of the forming stops the pressure of at least two edges previously bent in step f), with the male in the position of maximum insertion; Y [0268] j) pressing superiorly by contacting the overlapping portions of the flanges located in the corner areas of the box and previously bent towards the outside thereof, and gluing these flanges to one another by pressure in these overlapping portions by means of the Hot glue previously deposited in step d), is pressed and glued, being executed with the bottom of the box stopped and the male inserted inside the box in the position of maximum introduction. [0270] Similarly, in this preferred mode, after steps h), i) and j), step k) is executed. [0272] Complementarily, the method comprises step v) of immobilizing the upper end faces of the shaping stops in the respective stop positions, enabling a rapid formation of said edges. [0274] According to a third aspect, to overcome the drawbacks set forth in the previous section, the present invention presents a cardboard box formed from a previously punched flat plate. [0276] The associated blank sheet, from which this box is obtained, has cut lines and weakened fold lines. The fold lines can be crease and / or cut-crease lines, to facilitate the formation of the box by bending parts of the flat plate around them. [0277] The box can be made of corrugated (corrugated) cardboard or alternatively compact cardboard, among others, which provide the box with a certain rigidity to simplify its machine formation. [0279] The box comprises a bottom, and four side sides facing two by two surrounding the bottom. [0281] Likewise, the box includes four corner zones, each disposed between two respective adjacent side sides. [0283] Likewise, the box comprises two opposite side walls, each one attached to the bottom by means of a respective fold line, these opposite side walls being integral to two of the side sides. [0285] Also, the box comprises glue, preferably hot, applied directly or indirectly joining one side of the other. [0287] The box of the present invention also proposes, in combination, in a way per se not known from the existing state of the art, the following elements and characteristics. [0288] Each of the four box corner areas adjoining two side walls of the box are molded by creating a plurality of essentially linear wrinkles with each other in the box corner areas. [0290] Optionally, these linear wrinkles are arranged on the inside of the box. [0292] In each corner area of the box, this plurality of wrinkles may comprise, by way of illustration, between 10 and 25 essentially linear wrinkles, [0294] This molding with the creation of said linear wrinkles is carried out by means of a forming machine equipped with a mold with a cavity facing a linearly movable core through a cavity with a plate entrance mouth and a formed box exit mouth aligned. [0296] This plurality of wrinkles created provides an essentially curved surface in the box corner areas. [0298] The advantages of this box have been exposed in the first and second aspects of the invention. [0300] The box is optionally obtained by means of the machine of said first aspect, and / or optionally obtained by means of the method of the previously exposed second aspect. [0301] Preferably, the box is designed to be nested, wherein the four side sides facing two by two surrounding the bottom have respective inclinations with respect to bottom, and the essentially curved surface of each box corner area is in the shape of an inverted conical section. [0303] Preferably, the box further comprises at least four ridges parallel to the bottom, located at the top of each side side and bent towards the outside of the box. These at least four ridges define four lip overlapping portions, one associated with the top of each corner area of the box that join the at least four ridges to each other. These flange overlapping portions have respective applied at least one point or bead of hot glue joining one end of a respective flange to another. [0305] In a preferred box option: [0306] - two of said at least four edges are each located in respective upper parts of the two side walls, bent with respect to a respective bending line of the edge preferably towards the outside of the box; [0307] - four corner panels arise laterally from both ends of these two side walls to define the respective corner areas of the box; [0308] - a side flap is laterally adjacent to each corner panel; [0309] - four other edges each emerge from the upper part of each side flap in the flat development of the blank; Y [0310] - in said four edge overlapping portions, the at least one point or bead of hot glue join one end of a respective edge originating from the side walls with one end of a respective edge originating from the side flaps; and - each of the other two side sides are formed from the at least partial overlap of one side flap with the other by points or cords of cold or hot glue, and also optionally by another side wall attached to the bottom; Y [0311] the upper part of each of these other two lateral sides comprises an auxiliary overlapping portion between flanges arising from the lateral flaps having applied at least one point or bead of hot glue. [0313] In an alternative box option: [0314] - Four of the aforementioned at least four edges are each located in respective upper parts of four side walls attached to respective sides of the bottom by means of respective fold lines, and bent with respect to a respective edge fold line preferably towards the outside of the cash register; [0315] - four corner panels arise laterally from both ends of these two side walls to define the respective corner areas of the box; [0316] - a side flap is laterally adjacent to each corner panel; [0317] - in said four flange overlapping portions, the at least one point or bead of hot glue join the flange ends originating from the side walls with each other; Y [0318] - each of the other two side sides are formed from the overlap of both side flaps by means of respective points or strands of hot or cold glue with another side wall attached to the bottom; Y [0319] - Four reinforcement flaps arising from the bottom of lateral bends of the flanges on both sides of two opposite side walls, are connected with at least one point or bead of hot glue to respective corner area of the box. [0321] Complementary to this alternative option, each lateral bend has bend portions with a curved shape, finished in an overlapping end portion substantially parallel in the flat development of the plate to the end portion of the other joining flange. [0323] Preferably, in this alternative option, the box further comprises four other reinforcing flaps, joined with hot glue to respective corner area of the box, arising from the bottom of the lateral bends of the flanges on both sides of two opposite side walls. [0325] Preferably, in this alternative option, the box further comprises four other reinforcing flaps, joined with hot glue to respective lateral ends of the lateral walls, which originate inferiorly from the lateral bends of the flanges on both sides of two opposite lateral walls. [0327] In a preferred mode, the box is made of corrugated cardboard, with at least one smooth sheet and one corrugated sheet provided with corrugated undulations, these sheets being adhered to each other, and the plurality of essentially linear wrinkles being essentially parallel or perpendicular in the direction of the fluted ripples in the box corner areas. [0329] Preferably, the corrugated cardboard of the box comprises two smooth sheets and a corrugated sheet provided with grooved corrugations sandwiched between the smooth sheets, these sheets being adhered to each other. [0331] The present invention covers all possible combinations of particular and preferred embodiments indicated herein. For those skilled in the art, other objects, advantages and characteristics of the invention will emerge in part from the description and in part from the practice of the invention. Other embodiments can be made by those skilled in the art in light of this description without departing from the scope defined in the claims. [0332] The claims relating to the box-forming machine of the present invention have been expressly drawn up so that a possible infringement of this machine can be verified, even though it is not producing boxes at the time of inspection. [0333] BRIEF DESCRIPTION OF THE DRAWINGS [0335] The foregoing and other advantages and characteristics will be more fully understood from the following detailed relationships of exemplary embodiments with reference to the attached figures, which should be taken by way of illustration and not limitation, in which: [0337] Fig. 1 is a plate from which the box of Figs. 3 and 4, which has glue cords deposited by the forming machine of the present invention, and on which the grooves of the corrugated cardboard are artificially indicated; [0339] Fig. 2 is a sheet from which a second box embodiment of the third aspect of the present invention is formed; [0341] Figs. 3 and 4 are respective top perspective views of a first embodiment of the box of the present invention, where in Fig. 4 parts of the box have been artificially represented transparent to show the applied glue dots or beads, and the grooves of the corrugated cardboard; [0343] Fig. 5 is a top perspective view of a first embodiment of the machine of the present invention, with the male in the position of maximum extraction, and a flat plate located on the inlet mouth, according to an initial stage of the method of the present invention; [0345] Figs. 6 and 7 are side schematic views of the machine of the first embodiment, and according to an initial and later stage of the first method embodiment; [0347] Fig. 8 is a top perspective view of Fig. 1, where elements have been omitted to clearly show the core and the mold; [0349] Fig. 9 is the view of Fig. 8, with tap, shaping stops, and presses in positions of maximum introduction, stop, and pressing, respectively, according to a later stage of the first method embodiment; [0351] Fig. 10 is a bottom perspective view of Fig. 8; [0353] Fig. 11 is a side view of Fig. 8, where a plate is on the conveyor plate guides, positioned between the male and the inlet mouth; [0355] Fig. 12 is a cut away plan view of Fig. 8; [0356] Figs. 13 and 14 are respective plan views of a second and third embodiments of the machine mold; [0358] Fig. 15 is a sheet from which the third box embodiment of Fig. 16 is formed; [0360] Figs. 16 and 17 are top perspective views of a third and fourth box embodiments, respectively; [0362] Fig. 18 is a sheet from which a fifth box embodiment is formed; [0364] Figs. 19 and 20 are respective plates from which a sixth and seventh box embodiment are formed; [0366] Fig. 21 is the sixth box embodiment obtained from the plate of Fig. 19; [0368] Figs. 22-24 are respective plan views of four alternative embodiments of the core bender device of the machine of Fig. 25; [0370] Fig. 25 is a top perspective view of a second embodiment of the machine, for forming the boxes of Figs. 16, 17 and 21, and in which elements have been omitted to show the male and the mold in detail. [0372] Fig. 26 is the view of Fig. 25, with tap, forming stops, and presses in positions of maximum introduction, stop, and pressing, respectively, according to a later stage of the second embodiment of the method; [0374] Fig. 27 is a top perspective view of a third embodiment of the machine; [0375] Fig. 28 is a top perspective view of a symmetrical half of the mold of the machine of Fig. 27, where a box is located in the position of maximum insertion of the male; [0377] Figs. 29 and 30 are top and bottom perspective views, respectively, of one of the forming stops as an integral part of the mold of Figs. 27 and 28; [0379] Figs. 31 and 32 are top and bottom perspective views, respectively, of an alternative embodiment of shaping stops of the machine of Figs. 27 and 28; [0381] Fig. 33 is an exploded top perspective view of the core of Fig. 27, where the angled forming members have been omitted for clarity; Y [0382] Figs. 34 and 35 are plan views of the core of FIG. 27, showing retracted and protruding positions, respectively, of four of the eight forming members of the core device. [0383] DETAILED EXHIBITION OF IMPLEMENTATION MODES / EXAMPLES [0385] According to the first aspect of the present invention, reference 100 designates a machine (100) for the formation of boxes (B) intended to be nested, from the previously punched flat plates (P) shown in Figs. 1,2, 15, and 18 to 20. [0387] Figs. 3, 4, 16, 17 and 21 show boxes (B) capable of being formed in such a machine (100), where the boxes (B) are typically provided with a bottom and four lateral sides (CL) facing two by two surrounding the bottom (F), with respective convergent inclinations that cause the transverse and longitudinal measurements of the upper mouth of the box (B) to be greater than the measurements of the bottom (F), to allow nesting of boxes (B) with other These boxes (B) have at least four box corner areas (ZB) that separate two respective contiguous side sides (CL). The bottom (F) and / or the side walls (PL) of the box (B) may be provided with ventilation holes (not shown). [0389] Usually, the stamping of the plate (P) is carried out in a stamping machine. The die-cut plate (P) obtained has weakened cut lines and fold lines (LF, LL, LR). The cut lines are shown in solid lines in the figures relating to the plates (P). The fold lines (LF, LL, LR) shown in dashed lines can be crease and / or cut-crease lines, to facilitate the formation of the box (B) by bending parts of the flat plate (P) around to these lines. [0391] According to the first machine embodiment (100) of Figs. 5 to 12, it comprises a chassis (1), and a mold (50), a male drive (10) and a male (60), supported on the chassis (1). [0393] The mold (50) comprises a cavity (52) aligned with a core (60) according to a linear Z direction, and a plate entrance mouth (54) to the cavity (52) and an exit mouth (55) of the formed cavity box (52) aligned according to linear Z direction. In this example, linear Z direction corresponds to vertical. The outlet mouth (55) is dimensioned to evacuate the boxes formed from the cavity (52) through it. [0395] The male drive (10) is configured to move the male (60) guided in the linear direction Z in opposite directions, between positions of maximum extraction and insertion of the male (60) with respect to the cavity (52). [0397] In the position of maximum extraction of Figs. 5, 8, 10 and 11 the male (60) is outside the cavity (52), and in the position of maximum insertion of Fig. 9 the male (60) is inside the cavity (52). [0398] Figs. 6 and 7 schematically represent that the male drive (10) comprises a mechanism of bars configured to transform the movement of a rotating electric motor (not numbered) into the linear movement of an arm, at the end of which there is located a connection support ( 11) where the male (60) connects to the male drive (10). [0400] Prior to the positioning of the plate (P) in its centered position between the male (60) and the cavity (52) of Fig. 5, it is transported by means of a machine conveyor (100) supported on the chassis (1) and equipped with two linear guides (40), one on each side of the plate (P) to be transported. [0402] Figs. 6 and 7 show that the conveyor includes a rotary motor (12) and a rotational encoder (13) coupled to the rotary motor (12), which are connected to a control device. The rotary motor (12) is a rotary electric motor. [0404] This rotational encoder (13) and the rotary motor (12) are configured together to move a plate pusher (16) in a controlled manner according to a horizontal X linear transport direction perpendicular to the vertical linear Z direction, from a position initial Fig. 6 associated with the plate stack (P) supported a magazine (not shown), to the centered position of Fig. 5 associated with the entrance mouth (54). The thrust member (16) is embodied in a thrust pawl. [0406] The machine (100) further comprises a plurality of pressurizable glue injectors (45), and in this example heated, supported on the chassis (1), and arranged according to a horizontal linear direction Y transverse to the linear transport direction X. This it is also shown in the embodiment of Fig. 27. [0408] Returning to Figs. 6 and 7, these show that the glue injectors (45) are configured to deposit dots or beads of glue (CC) on predefined areas of the plate (P) during its transport as a function of the controlled position of the pusher member (16 ). This glue (CC) to be heated is heat-meltable glue. Alternatively it can be cold glue and the glue injectors (45) of this cold glue do not have resistive heating means. [0410] In this first embodiment, the glue (CC) applied on the plate (P), and having the box (B) formed, is shown in Figs. 1, 3 and 4. In Fig. 1, the continuous or discontinuous glue beads (CC) applied to the side flaps (SL) are parallel to each other and parallel to the transport direction X. [0412] The glue injectors (45) are configured to indirectly join by means of this glue (CC) four lateral sides (CL) of the box (B), facing two by two that surround the bottom (F) of the box (B) of Figs. 3 and 4, through the overlap of the side flaps (SL) with the short side walls (PL) on the short sides, and the union of these by means of the applied glue (CC) arranged between such side flaps (PL) and walls short sides (PL). [0414] For the formation of the box (B) of Fig. 4, continuous or discontinuous strands of glue (CC) deposited on the plate of Fig. 1 are necessary, specifically, on each of the four side flaps (SL ) derived on both sides of two mutually facing long side walls (PL). [0416] Figs. 3 and 4 show that the tail cords (CC) of the side flaps (SL) remain substantially parallel to the bottom (F) of the box (B) once it is formed. [0417] Alternatively these tail beads (CC) can be substantially perpendicular to the bottom (F) as shown in Fig. 17. [0419] In this embodiment, the tap (60), mold (50), and inlet and outlet ports (54, 55) are aligned with the linear direction Z corresponding to the vertical. The glue injectors (45) are arranged suspended on the horizontal linear guides (40) along the transport direction X perpendicular to the vertical linear direction Z. Also, the mold (50) is configured so that the boxes come out below the outlet mouth (55). [0421] After depositing the glue cords (CC) by means of the glue injectors (45), the plate (P) of Fig. 1 is positioned in the final centered transport position of Fig. 5. [0423] The male drive (10) supported on the chassis (1) moves the male (60) guided vertically towards the insertion position of the male (60) of Fig. 9, dragging the plate (P) into the cavity (52). [0425] The male (60) is essentially in the shape of an inverted truncated pyramid, with four flat lateral sides (62) arranged facing two by two around the connection support (11) forming respective inclinations with respect to the vertical linear Z direction. The four flat lateral sides (62) define four corner areas of the core (60), each between two respective flat lateral sides (62) inclined adjacent thereto. [0427] In Figs. 8 to 10, the core (60) comprises a front side and a rear side (61, 63) in the direction of insertion of the core (60) into the mold (50) in the linear Z direction. The front side (61) It comprises a flat bottom surface (65) integrated in the male (60) configured to press a bottom portion (F) of a flat plate (P) positioned in the inlet mouth (54) and insert it into the cavity (52) . [0428] Each corner area of the core (60) includes a convex curved surface (62a ') with an inverted conical section shape, complementary to a respective concave curved surface (S2) of the mold (50). [0430] In this first embodiment, the mold (50) further comprises two forming stops (56), mutually facing each other and arranged laterally around the cavity (52). [0432] Each of the shaping stops (56) is movable between a retracted position of Figs. 8, 10 and 12 adjacent to the cavity (52), to enable the insertion of the flat plate (P) to be formed in the cavity (52), and a stop position of Fig. 9, towards the interior of the cavity (52). [0434] Each of the shaping stops (56) is provided with two of said concave curved surfaces (S2) arranged laterally around the cavity (52), movable between said retracted and stop positions. [0436] Thanks to this mobility, the movable shaping stops (56) are configured to evacuate in the retracted position the boxes (B) formed from the cavity (52) passing through the outlet mouth (55) without interfering with the shaping stops (56). [0438] These movable concave curved surfaces (S2) are configured so that, in their stop positions and with the male (60) in the maximum insertion position, press the outside of the box (B) towards the inside of the cavity (52) , this outer part including the four corner areas of the box (ZB), against the four convex curved surfaces (62a ') of the core (60). [0440] In this first embodiment of the machine (100), it lacks a device for moistening the blank (P), and lacks a device for heating the concave curved (S2) and / or convex (62a ') surfaces. [0442] These devices that the machine (100) lacks are ones that are configured to provide humidity and heat substantially above the ambient humidity and temperature conditions where the machine (100) is located, respectively. [0443] According to this first embodiment, each of the two shaping stops (56) is configured to move by a respective stop actuator (36). [0445] Each of the two shaping stops (56) shown in detail in Figs. 8 to 12 has five side end faces (C1, S2, C4, S2, C1). [0447] A lateral flange surface corresponds to a lateral flange face (C4) with an inclination with respect to the linear direction Z, complementary to the inclination of a respective flat lateral side (62), configured to press in the stop position a lateral flank (CL) of the box (B) against that complementary flat lateral side (62). [0449] Two other side bearing surfaces correspond to two of said concave curved surfaces (S2), arranged adjacently one on each side of the side bearing face (C4). [0451] Two other lateral flange surfaces correspond to two lateral flange faces (C1) with respective inclinations with respect to the linear direction Z, complementary with inclinations of respective flat lateral sides (62), arranged adjacently one in each of said concave curved surfaces (S2 ). [0453] Each of these two other side end faces (C1) is configured to press in the stop position other respective opposite side sides (CL) of the box (B), against respective opposite flat side sides (62). [0455] The two shaping stops (56) provided with five side end faces (C1, S2, C4, S2, C1) each, are configured to move from the retracted position of Figs. 8, 10 and 12 towards the stop position of Fig. 9 by means of stop actuators (36). [0457] Each of the two shaping stops (56) is moved by a respective stop actuator (36) of the type that are movable upon change of a control signal generated by a control device (not shown). [0459] The stopper actuators (36) are pneumatic cylinders whose rods are moved by pressurized air, thanks to an electrical control signal received in a solenoid valve (not shown) that connects the pneumatic cylinder with the control device (not shown). [0460] The two shaping stops (56) aligned in the horizontal transverse Y direction each have a first stop member (57a). Each first stop member (57a) is attached to the movable rod (36b) of a respective stop pneumatic cylinder (36), each of the rods (36b) being guided by a cylinder guide device (37, 38) that guides each stem (36b) movable in the transverse direction Y. [0462] The immobilization of the five lateral support surfaces (C1, S2, C4, S2, C1), including the concave curved surfaces (S2), in the stop position of each forming stop (56), is configured to be executed by applying air to pressure on one of the two sides of the movable rod (36b) of the pneumatic cylinder. [0464] Each of the two shaping stops (56) have integrated four shaping edges (A50), eight in total, adjacent to the respective ends of the curved surfaces concave (S2) and with respective inclinations with respect to the linear Z direction. The molding edges (A50) are configured to cooperate with respective male edges (A60) adjoining the respective ends of the convex curved surfaces (62a ') of the male ( 60). [0466] Each first stop member (57a) of Figs. 8 to 12 is a cast nylon block where the five side end faces (C1, S2, C4, S2, C1) and the molding edges (A50) are machined. [0468] The four corner areas including the convex curved surfaces (62) of the core (60), eight core edges (A60), and four flat lateral sides (62) of the core (60) are machined onto another cast nylon block. [0470] In Figs. 8 to 12, each of said concave curved surfaces (S2) of the mold (50) includes a respective pressure surface of dimensions essentially corresponding to each of the convex curved surfaces (62a '). [0472] Also, the shaping edges (A50) of the shaping stops (56) have an edge segment of essentially coincident length with a respective male edge (A60). [0474] With the shaping stops (56) in the stop positions and with the male (60) in the inserted position of Fig. 9, the said four lateral end faces (C1, C4) are configured to maintain two different lateral separations with respect to the flat lateral sides (62) of the male (60): a first separation on two mutually opposite flat lateral sides (62) associated with the plate thickness (P), and a second separation on the other two flat lateral sides (62) mutually opposite associated with twice the plate thickness (P). [0476] The mold (50) further comprises two mutually facing presses (46), arranged laterally around the cavity (52). The presses are movable between the retracted position of Figs. 8, 10 and 12, towards the outside of the cavity (52), and the pressure position of Fig. 9, towards the inside of the cavity (52). [0478] To form the box (B) of Fig. 3, the presses (46) are moved from the retracted position of Fig. 8 to the pressure position of Fig. 9 once the forming stops (56) are in place. the stop position, as shown in Fig. 9. The presses (46) are configured to press in the pressure position the outer part of the box (B) on two opposite lateral sides (CL) of the box (B) , against respective opposite flat lateral sides (62) of the male (60). [0479] Each press (46) is attached to a respective movable rod (47b) of a respective pneumatic press cylinder (47) supported on a fixed support (21) of the chassis (1). Each of the rods (47b) is guided by a respective cylinder guide device (37) in the longitudinal direction X. [0481] The aforementioned five lateral support surfaces (C1, S2, C4, S2, C1) of each of the two forming stops (56) are configured to join by means of said pressure some lateral sides (CL) of the box (B) with others , by means of glue dots or cords (CC) previously applied with precision on preselected areas of the plate (P) by the plurality of glue injectors (45), as shown in Fig. 1. The presses (46) increase the pressure of the side flaps (SL) against the side walls (PL) on these sides of the box (B) to reinforce this connection. [0483] Once the presses (46) have pressed, they and the forming stops (56) return, preferably simultaneously, to their respective retracted positions, and the formed box (B) passes through the outlet mouth (55) without interfering with the forming stops (56). [0485] The second machine embodiment (100) comprises all the elements and characteristics of the first embodiment, except for the mold (50) shown in Fig. 13, which now comprises four auxiliary shaping stops (56 '), mutually facing each other in pairs and arranged laterally around the cavity (52). [0487] Also, this mold (50) comprises four forming stops (56) positioned at the respective corners of the cavity (52) and alternately with the auxiliary forming stops (56 '). [0489] Each of these four auxiliary shaping stops (56 ') is provided with a first stop member (57a) with a lateral end face (C1, C4) of inclination complementary to that of a respective flat lateral side (62), this being at least one lateral end face (C1, C4) movable by means of a stop actuator (36) between a retracted position to enable the insertion of the flat plate (P) to be formed in the cavity (52), and a stop position, into the cavity (52). [0491] The movable auxiliary shaping stops (56 ') are configured to evacuate in the retracted position the boxes (B) formed from the cavity (52) passing through the outlet mouth (55) without interfering with the auxiliary shaping stops (56'). [0493] The third embodiment of machine (100) comprises all the elements and characteristics of the first embodiment, except for the mold (50) shown in Fig. 14 which comprises likewise two shaping stops (56), but in a different shape, each one of them has three lateral end faces (S2, C4, S2). [0495] One of these three lateral flange surfaces corresponds to a lateral flange face (C4) with an inclination with respect to the linear direction Z, complementary to the inclination of a respective flat lateral side (62), configured to press a flank in the stop position. side (CL) of the box (B) against that complementary flat side (62). [0497] The other two lateral nose surfaces correspond to two of said concave curved surfaces (S2), arranged adjacently one on each side of the lateral nose face (C4). [0499] The fourth machine embodiment (100) of Figs. 25 and 26 is useful for forming the boxes (B) of Figs. 16, 17 and 21, and the boxes (B) obtained from the plates (P) of Figs. 15, and 18 to 20. In addition, it can also form the box (B) of Figs. 3 and 4, and the box (B) obtained from the plate (P) of Fig. 2. [0501] This fourth embodiment of machine (100) comprises all the elements and characteristics of the first embodiment, and furthermore the elements described below. [0503] Each of the two shaping stops (56) includes an upper end face (58, 59), configured to receive pressure, with the male (60) in the maximum insertion position and with the shaping stops (56) in the position. top of Fig. 26, of some flanges (R) arranged in the upper part of the lateral sides (CL) of the box (B) previously bent outwards by a male bending device. [0505] The male bender device is mounted on the rear side (63) of the male (60), and comprises four paired-facing forming members (64a) and four pair-facing corner-forming members (64b). [0507] These eight forming members are arranged around the connection support (11) and in use positioned protruding towards the outside of the male (60) configured to bend the said flanges (R) outwards, each forming member (64a) being associated with a respective flat lateral side (62) and each corner forming member (64b) positioned in a corner area of the core (60) sandwiched between two adjoining forming members (64a). [0509] The four corner forming members (64b) are configured to press, with the male (60) positioned in the position of maximum insertion of Fig. 26, superiorly by contacting overlapping portions (A) of the flanges (R) located in the corner areas of the box (B), and glue these flanges (R) against others by pressure and hot glue, deposited by pressurizable and heated glue injectors (45) in these overlapping portions (A). [0511] Fig. 22 shows a first alternative embodiment of the male bender device, wherein the four forming members (64a) are embodied in a single piece, while the four corner forming members (64b) are embodied in respective individual pieces. [0513] Fig. 23 shows a second alternative embodiment of the male bender device, wherein two of the forming members (64a) have at both of their longitudinal ends extensions corresponding to the corner forming members (64b). [0515] Alternatively, the four corner forming members may emerge one from one end of each of the four forming members (64a). [0517] Fig. 24 shows a third alternative embodiment of the male bender device, wherein all of the forming members (64) and corner forming members (64b) are integrated into a single piece. [0519] Alternatively, the forming members of the core bender device may be machined on the same core core that integrates the flat lateral sides (62) and / or the convex curved surfaces (62a ') of the core corner areas (60). [0521] The fourth machine embodiment (100) of Figs. 27 to 30 comprise all the elements and characteristics of the first embodiment except for some variations described below. [0523] The mold (50) comprises first and second benders (51, 53) facing each other in pairs, closer to the entrance mouth (54) than the forming stops (56), configured to bend four mutually opposite side walls (PL) in pairs by respective fold lines that separate them from the bottom (F) of the plate (P) of Figs. 15 or 18, prior to the positioning of the shaping stops (56) in the stop position. [0525] In Fig. 28, the machine (100) comprises a guiding device associated with said mold (50), provided with four box guides (90) mutually facing each other in pairs, configured to guide the boxes (B) formed through said mouth outlet (55), in a nested arrangement, one with the other, forming a stack of boxes (B). [0527] In this example, the guiding device is associated with the mold (50) in such a way that it is an integral part of the same and each of its guides (90) are fixedly supported with respect to a second bender (53). [0529] In Figs. 27 to 30, the mold (50) comprises four shaping stops (56), mutually facing each other in pairs, along a double axis of symmetry with the longitudinal and transverse horizontal linear directions X, Y, and arranged around the cavity (52), each in one of the four corner areas of the cavity (52). [0531] In Figs. 29 and 30, each of these shaping stops (56) is movable, by activating a stop actuator (36) embodied in a pneumatic cylinder, between the retracted position of Figs. 27-30 adjacent to the cavity (52) where it does not interfere with the box (B) to be formed, and a stop position (not shown). [0533] Each of these shaping stops (56) comprises a stop member (57) comprising first and second stop members (57a, 57b). [0535] Figs. 28 to 30 show that the machine (100) comprises essentially vertical side support surfaces (C1, S2, S2, C4) provided with an inclination integrated in the first and a second stop members (57a, 57b) of the shaping stops (56 ). This inclination and shape of the lateral support surfaces (C1, S2, S2, C4) correspond to the box corner zones (ZB) to be formed. These side end face surfaces (C1, S2, S2, C4) are configured to press the outer part of the box (B) in its abutment position in each of said box corner areas (ZB) against respective corner areas of the male. (60). [0537] Each first stop member (57a) comprises two side end faces (C4, S2), a side end face (C4) and a concave curved surface (S2) at an angle, which defines a molding edge (A50) that assists in bending. of a respective essentially linear wrinkle (AL) laterally bordering a box corner area (ZB) shown in Figs. 16, 17 and 28. [0539] Each second stop member (57b) comprises two other nose faces (C1, S2), materialized in another lateral nose face (C1) and another concave curved surface (S2), forming another angle, which defines a molding edges (A50) that aids in the folding of a respective essentially linear wrinkle (AL) laterally bordering a box corner area (ZB) shown in Figs. 16, 17 and 28. [0541] Thus, the mold (50) of four forming stops (56) comprises sixteen side end surfaces, four of them for each forming stop (56). [0543] The side end faces (C1, S2, S2, C4) of each stop member (57) do not include respective pressure surfaces of dimensions essentially matching each other. of the counter-pressure surfaces of two of the flat lateral sides (62) of the core (60), but have smaller dimensions. [0545] Correspondingly, the molding edges (A50) of each stop member (57) do not include respective edge portions of essentially coincident lengths with each of the core edges (A60) positioned in the corner areas of the core (60), but rather they are shorter in length. [0547] In Figs. 29 and 30, each pneumatic cylinder is configured to linearly move the first stop member (57a), which is operatively connected to the second stop member (57b) by a screw (22) attached to the first stop member (57a) and a spring (20) that keeps the second stop member (57b) in contact against said screw (22) that acts as a cam follower. [0549] As the pneumatic cylinder rod exits, the first stop member (57a) and screw (22) move linearly into the cavity (52), causing the second stop member (57b) to rotate from a retracted position. towards the inside of the cavity (52), leaving the four lateral end surfaces (C1, S2, S2, C4) in the stop position. [0551] When the piston rod of the pneumatic cylinder enters, the first and second stop members (57a, 57b) of the stop member (57) move from the stop position to the retracted position, allowing the formed boxes (B) to pass through the mouth. outlet (55) without interfering against the stop member (57) of the former stop (56). [0553] In Figs. 33 to 35, a male actuator (66) is configured to move the forming members (64a) linearly, each in a linear expansive direction not aligned and perpendicular to the vertical linear Z direction, between the protruding position of Fig. 35 , where they protrude outward from the flat lateral sides (62), and a retracted position of Fig. 34 where they do not protrude outward from said flat lateral sides (62). [0554] Alternatively, the forming members (64a) can pivot between the retracted and protruding positions around hinges, as described in Spanish patent application document P202030190. [0556] In the alternative embodiment of Figs. 31 and 32, each of the shaping stops (56) are moved by two stop actuators (36), one to move the first stop member (57 a) of the stop member (57), and the other to move the stop member (57 a). second stop member (57b) of stop member (57). [0557] The second aspect of the invention relates to a method of forming cardboard boxes (B) intended to be nested, from previously punched flat plates (P). [0558] The method is executed by the forming machine (100) of Figs. 5 to 12, provided with a mold (50) with a cavity (52) facing a male (60) linearly movable through the cavity (52). [0560] The first method embodiment comprises the following steps: [0562] z) placing in the magazine (not shown) of the machine (100) of Fig. 6 a plurality of sheets (P) of corrugated cardboard of Fig. 1 previously punched out provided with cut and fold lines, forming the stack of plate plates (P) of Fig. 6; [0564] a) displacing a core (60) that is essentially in the shape of an inverted truncated pyramid, according to a linear Z direction, between positions of maximum extraction (Figs. 5 and 8) and insertion (Fig. 9) of the core (60) with respect to the cavity (52); [0566] y) moving the plate (P) according to a linear transport direction X perpendicular to the Z direction from the initial position of Fig. 6, to the position of Fig. 5 on an inlet mouth (54) to the cavity ( 52); [0568] b) pressing by means of said male (60) a bottom portion (F) of the plate (P) inserting it into said cavity (52); [0570] c) directly or indirectly joining some side walls (PL) of the box (B) with others with dots or glue cords (CC) deposited on the plate (P), as illustrated in Figs. [0571] 4 and 7; [0573] e) after steps b) and c), fold four side walls (PL) attached to the bottom portion (F) of the box (B) to be formed in Fig. 3 by means of the mold (50) in cooperation with respective sides flat sides (62) of the male (60) distributed around the linear direction Z and with respective inclinations with respect to it; [0575] g) evacuating the boxes (B) formed from the cavity (52) passing through an outlet mouth (55) of the mold (50) aligned in a linear direction Z with the inlet mouth (54), as shown in Fig. 7 ; [0577] h) moving a plurality of shaping stops (56) of the mold (50), each provided with at least one concave curved surface (S2) with the shape of an inverted conical section arranged laterally around the cavity (52), from the retracted position of Fig. 8, to be able to insert the plate (P) to be formed in the cavity (52), up to the stop position of Fig. 9, towards the interior of the cavity (52); [0579] l) immobilize the concave curved surfaces (62) of the shaping stops (56) in their respective stop positions; [0581] m) press by means of the aforementioned concave curved surfaces (S2), the outer part of the box (B) including the four corner zones thereof, towards the inside of the cavity (52), against respective corner zones of the male ( 60) that each include a convex curved surface (62a ') with an inverted conical section shape, complementary to a respective concave curved surface (S2), each convex curved surface (62a') being arranged between two flat lateral sides ( 62) contiguous inclinations of the male (60), as shown in Fig. 9; [0583] x) molding each of the four box corner zones (ZB) contiguous to two side walls (PL) of the box (B), creating a plurality of wrinkles essentially linear with each other in the box corner zones (ZB) during steps h) and / or m), this plurality of wrinkles creating the essentially curved surface with an inverted conical section shape in the box corner areas (ZB) of Figs. 3 and 4; [0585] k) moving the shaping stops (56) from their stop position to the retracted position to allow stage g) of evacuating boxes (B) without interfering with the shaping stops (56), after steps m) and x); [0587] w) Move a thrust member (16) in a controlled manner according to the linear transport direction X, by means of a rotary motor (12) and a rotational encoder (13) coupled to the rotary motor (12), to move the plate (P) from the stage y) controlled, as shown in Figs. [0588] 5 to 7; Y [0590] u) depositing points or strands of hot glue (CC) during stage w), to carry out stage c), this deposition being a function of the position of the push member (16) according to the controlled movement of stage w). [0592] This first method embodiment lacks the steps of moistening the plate after punching step z), and of heating the concave (S2) and convex (62a ') curved surfaces, above, to a temperature necessary to melt said hot glue. of the humidity and environmental temperature conditions where the machine is located (100). [0594] In the method, step m) further comprises pressing two opposite side walls (PL) attached to the bottom portion (F) of the box (B) against two mutually opposite flat side sides (62) of the male (60), by means of two flat side end faces (C4) of the mold (50) mutually opposite and with respective inclinations with respect to the linear direction Z, movable between the retracted position of Fig. 8 and the top position of Fig. 9. Each of these Flat side end faces (C4) is arranged between two concave curved surfaces (S2). [0595] The die-cut plates (P) of Fig. 1 from which the box (B) of Figs. 3 and 4 is formed are made of corrugated cardboard. This corrugated cardboard comprises two smooth sheets and a corrugated sheet provided with corrugated undulations (OA) sandwiched between the smooth sheets, these sheets being adhered to each other. [0597] In molding step x), the plurality of essentially linear wrinkles (AL) of Figs. 3 and 4 are essentially perpendicular to the direction of the fluted undulations (OA) in the box corner areas (ZB). [0599] Alternatively (in an option not shown), in this method, the plurality of essentially linear wrinkles (AL) are essentially parallel to the direction of the fluted undulations (OA). [0601] In this method of the first embodiment, molding step x) lacks the step of folding and overlapping portions of the corner area of the box (ZB) so that in these portions the thickness of the lateral contour of the box (B ) is equal to or greater than three times the thickness of the previously stamped plate (P), this triple thickness being associated with Z-shaped folds. [0603] In the second embodiment of the method, this is carried out by means of a forming machine (100) equipped with a mold (50) with a cavity (52) facing a male (60) linearly movable through the cavity (52) of Figs. . 25 and 26. [0605] This second method embodiment comprises all the steps and characteristics of the first method embodiment except that the obtaining of the box of Fig. 16 from the die-cut plate (P) of Fig. 15 is now illustrated, for which , the method also comprises the steps of: [0607] d) apply points or cords of hot glue (CC) on overlapping portions (A) of outer flanges (R) located in the upper part of the lateral sides (CL) of the box (B) formed, to join some flanges (R) with the others; [0609] f) bending the four flanges (R) towards the outside of the box (B), by means of a male bending device mounted on a rear side (63) of the male (60); [0611] i) receiving on the upper end faces (58, 59) of the forming stops (56) the pressure of at least two flanges (R) previously bent in step f), with the male (60) in the position of maximum introduction from Fig. 26; [0613] v) to immobilize the upper end faces (58, 59) of the shaping stops (56) in the respective stop positions of Fig. 26, enabling a rapid formation of said edges; [0614] j) pressing superiorly by contacting the overlapping portions (A) of the edges (R) located in the corner areas of the box (B) and previously bent towards the outside of the same, and gluing these edges (R) one with the others by pressure in these overlapping portions (A) by means of the hot glue (CC) previously deposited in stage d), this pressed and glued being executed with the bottom (F) of the box (B) stopped and the male (60) inserted inside the box (B) in the position of maximum introduction of Fig. 26. [0616] In this second method embodiment, after steps h), i) and j), step k) is executed. [0617] The third aspect of the invention is related to a cardboard box (B) formed from a previously punched flat plate (P), which has weakened cut lines and fold lines (LL, LR). The fold lines (LL, LR) can be crease and / or cut-crease lines, to facilitate the formation of the box (B) by bending parts of the flat plate (P) around these lines. [0619] The box (B) comprises a bottom (F), and four side sides (CL) facing two by two surrounding the bottom (F). Likewise, the box (B) includes four corner areas, each one arranged between two respective contiguous side sides (CL). Likewise, the box (B) comprises two opposite side walls (PL), each one attached to the bottom (F) by means of a respective fold line (LF), and members of two of the side sides (CL). Also, the box (B) comprises hot glue (CC) applied directly or indirectly joining some lateral sides (CL) with others. [0621] Each of the four box corner areas (ZB) adjoining two side walls (PL) of the box (B), are molded by creating a plurality of essentially linear wrinkles (AL) relative to each other in the corner areas cash (ZB). [0623] This molding with the creation of the mentioned linear wrinkles (AL) inside the box (B) is carried out by means of a forming machine (100) equipped with a mold (50) with a cavity (52) facing a male (60) linearly movable through a cavity (52) with an inlet mouth (54) of the plate (P) and an outlet mouth (55) of the box (B) formed aligned, which corresponds to any one of the machine embodiments (100) of the first aspect of the invention. [0625] This plurality of wrinkles (AL) created provide an essentially curved surface in the box corner areas (ZB). [0627] The first box embodiment (B) of Figs. 3 and 4 obtained from the die-cut plate (P) of Fig. 1 is obtained by the first embodiment of the method of the second aspect of the invention, implemented in the machine (100) of Figs. 5 to 12. [0628] In Figs. 3 and 4, the box (B) is intended to be nested, where the four lateral sides (CL) facing two by two surrounding the bottom (F) have respective inclinations with respect to the bottom (F), and the essentially curved surface of each Box corner zone (ZB) is shaped like an inverted conical section. [0630] The box (B) is made of corrugated cardboard, with two smooth sheets and a corrugated sheet provided with corrugated undulations (OA) sandwiched between the smooth sheets, these sheets being adhered to each other. [0632] The ten essentially linear wrinkles (AL) in each box corner region (ZB) of Fig. 4 are essentially perpendicular to the direction of the fluted undulations (OA). [0633] In the box (B) of Fig. 4, the plate (P) has been placed in the machine (100) aligned with the transport direction X of Fig. 1. Thus, the continuous or continuous glue cords (CC) discontinuous in Fig. 4 are essentially parallel to each other and perpendicular to the essentially linear (AL) wrinkles. The side flaps (SL) are outside the box (B). [0635] The comparison of the plates of Figs. 1 and 2 associated with the first and second embodiments, exemplify that the formation of the box (B) of Figs. 3 and 4 by means of the aforementioned machine (100) it is produced efficiently with the flat plate (P) previously punched with (Fig. 2) or without (Fig. 1) lateral fold lines (LL) that separate corner panels (PZ) that will form the corner areas of the box (ZB) and / or the side flaps (SL), of the side walls (PL) attached to the bottom (F) of the box (B). [0637] The subsequent embodiments of the box described further comprise at least four ridges (R) parallel to the bottom (F), located on the upper part of each side side (CL) and bent towards the outside of the box (B), obtaining said box (B) by means of the second machine embodiment of Figs. 25 and 26 and the second method embodiment. [0638] These at least four flanges (R) define four flange overlapping portions (A), one associated with the upper part of each corner area of the box (ZB) that join the at least four flanges (R) to each other. These flange overlapping portions (A) have respective applied at least one point or bead of hot glue (CC) joining one end of a respective flange (R) to another. [0640] The third embodiment of box (B) of Fig. 16 obtained from the die-cut plate (P) of Fig. 15 four flanges (R) are located, each one, in respective upper parts of four side walls (PL) attached to respective sides of the bottom (F) by respective fold lines (LF), and folded with respect to a respective lip fold line (LR) towards the outside of the box (B). [0641] In Fig. 16, four corner panels (PZ) emerge laterally from both ends of these two side walls (PL) to define the respective corner areas of the box (ZB), and a side flap (SL) is laterally adjacent to each corner panel (PZ). [0642] In the aforementioned four overlapping portions (A) of flange of Fig. 16, the at least one point or bead of hot glue (CC) join with each other the ends of flange (R) originating from the side walls (PL ). [0644] Each of the other two lateral sides (CL) are formed from the overlap of both lateral flaps (SL) by means of respective points or cords of hot or cold glue (CC) with another lateral wall (PL), attached to the bottom (F ) using a fold line (LF). [0645] In Fig. 16, four reinforcement flaps (SR) originating from below from lateral bends (E) of the flanges (R) on both sides of two opposite side walls (PL), are joined with at least one point or cord of hot glue (CC) to respective corner area of the box (ZB). [0647] In the fourth embodiment of the box (B) of Fig. 17 the plate (P) has been placed in the machine (100) by rotating it 90 degrees with respect to the transport direction X shown in Fig. 15. Thus, the glue cords Continuous or discontinuous (CC) of Fig. 17 are essentially parallel to each other and essentially parallel to the essentially linear wrinkles (AL). The side flaps (SL) are inside the box (B). [0649] The fifth embodiment of box (B) obtained from the plate of Fig. 18, comprises all the elements and characteristics of the third embodiment, except that each lateral bend (E) has three bend portions (E1, E2, E3) with curved shape, finished in an overlapping end portion (E3) substantially parallel in the flat development of the plate (P) to the end portion of the other joining flange (R). [0651] In the box (B) obtained from the sheet (P) Fig. 18, it also comprises four other reinforcing flaps (SR), joined with hot glue (CC) to the respective corner area of the box (ZB), which they arise inferiorly from a proximal portion (E1) of the lateral bends (E) of the flanges (R) on both sides of two opposite lateral walls (PL). [0652] Also, the box (B) further comprises four other reinforcing flaps (SR), joined with hot glue (CC) to respective lateral ends of the lateral walls (PL), which originate inferiorly from an intermediate portion (E2) the lateral bends (E) of the flanges (R) on both sides of two opposite side walls (PL). This intermediate portion (E2) is located between the proximal and end portions (E1, E3). [0653] In the sixth embodiment of box (B) of Fig. 21 obtained from the die-cut plate (P) of Fig. 19, two of the aforementioned at least four edges (R) are each located in respective upper parts of the two side walls (PL), folded with respect to a respective flange fold line (LR) towards the outside of the box (B). [0655] Also, four corner panels (PZ) arise laterally from both ends of these two side walls (PL) by means of fold lines (LL) to define the respective corner areas of the box (ZB), and a side flap (SL) it is laterally adjacent to each corner panel (PZ) and separated by a crease line (LL). [0657] Furthermore, four other ridges (R) each arise from the upper part of each side flap (SL) in the flat development of the die-cut plate (P). [0659] In these four flange overlapping portions (A), the hot glue (CC) joins one end of a respective flange (R) originating from the side walls (PL) with one end of a respective flange (R) originating from the side flaps (SL). [0661] In Fig. 21, each of the other two lateral sides (CL) are formed from the at least partial overlap of one side flap (SL) with the other (SL) by hot glue cords (CC). Alternatively, this glue (CC) can be cold. [0663] In Fig. 21, the upper part of each of these other two lateral sides (CL) comprises an auxiliary overlapping portion (AX) between flanges (R) arising from the lateral flaps (SL) having applied at least one point or hot bead (CC). [0664] This box (B) is obtained by implementing the method of the second embodiment in the machine (100) of Figs. 25 and 26. [0666] The seventh embodiment of the box (B), obtainable from the plate (P) of Fig. 20, comprises all the elements and characteristics of the sixth embodiment, and also each of these other two sides (CL) are formed by another side wall (PL) attached to the bottom (F) by means of a fold line (LF).
权利要求:
Claims (34) [1] 1.- Machine (100) for forming cardboard boxes (B) intended to be nested, from previously stamped flat plates (P), the machine (100) comprising: - a chassis (1); - a mold (50) supported on the chassis (1), comprising a cavity (52) aligned with a male (60) according to a linear Z direction, a plate entrance mouth (54) to the cavity (52), and an outlet mouth (55) of the box formed from the cavity (52), aligned according to the linear direction Z, and the outlet mouth (55) being sized to evacuate the boxes formed from the cavity (52) through it; - A male drive (10) supported on the chassis (1), configured to move the male (60) guided in the linear direction Z in opposite directions, between positions of maximum extraction and insertion of the male (60) with respect to the cavity (52); - said male (60), connected by means of a connection support (11) to the male drive (10), the male (60) having essentially the shape of an inverted truncated pyramid, with four flat lateral sides (62) arranged opposite each other. two around the connection support (11) forming respective inclinations with respect to the linear direction Z, the four flat lateral sides (62) defining four corner areas of the male (60), each one between two respective inclined flat lateral sides (62) contiguous thereto, and the male (60) comprising a front and rear side (61, 63) according to the direction of introduction of the male (60) into the mold (50), wherein the front side (61) comprises a surface flat bottom (65) integrated in the male (60) configured to press a bottom portion (F) of a flat plate (P) positioned in the inlet mouth (54) and insert it into the cavity (52); characterized because Each corner area of the core (60) includes a convex curved surface (62a ') with an inverted conical section shape, complementary to a respective curved concave surface (S2) of the mold (50); The mold (50) further comprises a plurality of shaping stops (56), mutually facing and arranged laterally around the cavity (52), each one being movable between a retracted position, adjacent to the cavity (52), to enable insertion of the flat plate (P) to be formed in the cavity (52), and a stop position, towards the interior of the cavity (52); each of the shaping stops (56) is provided with at least one of said concave curved surfaces (S2) arranged laterally around the cavity (52), movable between said retracted and stop positions, the shaping stops (56) being movable configured to evacuate in the retracted position the boxes (B) formed from the cavity (52) passing through the outlet mouth (55) without interfering with the shaping stops (56); These concave curved surfaces (S2) are configured to press the outside of the box (B) including four corner areas (ZB) thereof, towards the inside of the cavity (52), against the four convex curved surfaces (62a ') of the male (60); Y and because the machine (100) further comprises: a conveyor supported on the chassis (1), equipped with two linear guides (40), one on each side of the plate to be transported, a rotary motor (12) and a rotational encoder (13) coupled to the rotary motor (12), jointly configured to move a plate pusher member (16) in a controlled manner according to a linear transport direction X perpendicular to the linear direction Z, from an initial position to a position associated with the inlet mouth (54); a plurality of pressurizable and preferably heated glue injectors (45), supported on the chassis (1), and arranged transversely to the linear transport direction X, configured to deposit dots or beads of glue (CC) on the plate (P) during transport depending on the controlled position of the push member (16) and directly or indirectly join by means of this glue four lateral sides (CL) of the box (B), facing two by two, surrounding the bottom (F) of the the same. [2] 2. - The machine (100) according to claim 1, further characterized in that it lacks a device for moistening the die-cut plate (P), and lacks a device for heating the concave curved surfaces (S2) and / or convex (62a '). [3] 3. - The machine (100) according to claim 2, wherein the concave curved surfaces (S2) are configured to be immobilized in the respective stop positions. [4] 4. - The machine (100) according to any one of claims 1 to 3, wherein the mold (50) comprises two shaping stops (56), each with three lateral end surfaces (S2, C4, S2): one corresponds to a lateral flange face (C4) with an inclination with respect to the linear direction Z, complementary to the inclination of a respective flat lateral side (62), configured to press in the stop position a lateral flank (CL) of the box (B) against that complementary flat lateral side (62); and two others correspond to two of the aforementioned concave curved surfaces (S2), arranged adjacently one on each side of the lateral end face (C4). [5] 5. - The machine (100) according to claim 4, wherein each of the two shaping stops (56) comprises five lateral support surfaces (C1, S2, C4, S1, C1), with two other lateral support faces (C1 ) with respective inclinations with respect to the linear direction Z, complementary with inclinations of respective flat lateral sides (62), arranged adjacently one in each of said concave curved surfaces (S2), each one of these other two lateral support faces ( C1) configured to press in the stop position other respective opposite lateral sides (CL) of the box (B), against respective opposite flat lateral sides (62). [6] 6. - The machine (100) according to any one of claims 1 to 3, wherein the mold (50) comprises four shaping stops (56), each comprising two lateral support surfaces (S2, C4): one corresponds with a lateral support face (C4) with an inclination with respect to the linear direction Z, complementary to the inclination of a respective flat lateral side (62), configured to press in the stop position a lateral side (CL) of the box ( B) against a flat lateral side (62) of the core (60); and the other corresponds to said concave curved surface (S2). [7] 7. - The machine (100) according to claim 6, wherein each of the shaping stops (56) comprises three lateral support surfaces (C1, S2, C4): a concave curved surface (S2), and two lateral support faces (C1, C4) with respective inclinations with respect to the linear direction Z, complementary with inclinations of respective flat lateral sides (62), flanking the concave curved surface (S2), these three surfaces being configured to press an area in the stop position corner of the box (B) and both lateral sides (CL) of the box (B) bordering it, against a corner area of the male (60) and portions of the flat lateral sides (62) bordering it. [8] 8. - The machine (100) according to any one of claims 1 to 3, wherein the mold (50) comprises: - four auxiliary shaping stops (56 '), mutually facing each other in pairs and arranged laterally around the cavity (52), each one of them equipped with at least one lateral end face (C1, C4) with an inclination complementary to that of a respective flat lateral side (62), the at least one lateral flange face (C1, C4) being movable between a retracted position to enable the insertion of the flat plate (P) to be formed in the cavity (52), and a stop position , towards the interior of the cavity (52), the auxiliary shaping stops (56 ') being movable configured to evacuate in the retracted position the boxes (B) formed from the cavity (52) passing through the outlet mouth (55) without interfering with the auxiliary shaping stops (56 '); Y - four shaping stops (56) positioned at the respective corners of the cavity (52) and alternately with the auxiliary shaping stops (56 '). [9] 9. - The machine (100) according to any one of claims 1 to 8, wherein the shaping stops (56) have integrated eight molding edges (A50) adjoining the respective ends of the concave curved surfaces (S2) and with respective inclinations with respect to the linear Z direction, configured to cooperate with respective male edges (A60) abutting the respective ends of the convex curved surfaces (62a '). [10] 10. - The machine (100) according to any one of claims 4 to 8, wherein they are mechanized or fixedly coupled on blocks of nylon, preferably cast nylon, the side support surfaces (C1, S2, C4) that are optionally separated by respective molding edges (A50) of the forming stops (56), and the corner areas of the core (60) that optionally include respective core edges (A60). [11] 11. - The machine (100) according to any one of claims 3 to 10, wherein each of said concave curved surfaces (S2) of the mold (50) includes a respective pressure surface of dimensions essentially corresponding to each of the Convex curved surfaces (62a '), and optionally shaping edges (A50) of the shaping stops (56) have an edge segment of essentially coincident length with a respective male edge (A60). [12] 12. - The machine (100) according to claim 11 and any one of claims 5 to 8, wherein at least four lateral support faces (C1, C4) are configured to maintain two different lateral separations with respect to the flat lateral sides ( 62) of the male (60): a first separation on two mutually opposite flat lateral sides (62) associated with the plate thickness (P), and a second separation on the other two mutually opposite flat lateral sides (62) associated with the double the plate thickness (P). [13] 13. - The machine (100) according to claim 12, wherein the mold (50) comprises two mutually facing presses (46), arranged laterally around the cavity (52), and movable between a retracted position towards the outside of the cavity (52) and a pressure position towards the interior of the cavity (52), configured to press in the pressure position the outer part of the box (B) on two opposite side sides (CL) of the box (b) , against respective opposite flat lateral sides (62) of the male (60). [14] 14. - The machine (100) according to any one of claims 1 to 13, wherein male (60), mold (50), and inlet and outlet openings (54, 55) are aligned with the linear direction Z according to the vertical, and the glue injectors (45) are arranged suspended on the linear guides (40), which are horizontal. [15] 15. - The machine (100) according to any one of claims 1 to 14, wherein: Each of the shaping stops (56) includes an upper end face (58, 59), configured to receive the pressure of some flanges (R) arranged in the upper part of the lateral sides (CL) of the box (B) previously bent outwards by a rear-side-mounted male bender device (63) comprising four paired-facing forming members (64a) and four pair-facing corner-forming members (64b) arranged around the connection bracket (11), each forming member (64a) associated with a respective flat lateral side (62) and each corner forming member (64b) positioned in a corner area of the core (60) sandwiched between two contiguous forming members (64a), these eight forming members (64a) , 64b) being in use positioned protruding out of the core (60); Y The four corner forming members (64b) are configured to press superiorly by contact overlapping portions (A) of the ridges (R) located in the corner areas of the box (B), and to glue these ridges (R) against each other by pressure and hot glue deposited by the glue injectors (45) in these overlapping portions (A). [16] 16- Method of forming cardboard boxes (B) intended to be nested, from previously punched flat plates (P), by means of a forming machine (100) equipped with a mold (50) with a cavity (52) facing the a male (60) movable linearly through the cavity (52), the method comprising the steps of: z) placing in the machine (100) said previously punched plate (P) provided with cutting and folding lines; a) displacing a core (60) essentially having the shape of an inverted truncated pyramid, according to a linear Z direction, between positions of maximum extraction and insertion of the core (60) with respect to the cavity (52); y) moving the plate (P) according to a linear transport direction X perpendicular to the Z direction from an initial position to a position on an entrance mouth (54) to the cavity (52); b) pressing by means of said male (60) a bottom portion (F) of the plate (P) inserting it into said cavity (52); c) joining directly or indirectly some side walls (PL) of the box (B) with others with dots or glue cords (CC) deposited on the plate (P); e) after steps b) and c), bend at least two side walls (PL) attached to the bottom portion (F) of the box (B) to be formed by the mold (50) in cooperation with respective flat side sides ( 62) of the male (60) distributed around the linear direction Z and with respective inclinations with respect to it; g) evacuating the boxes (B) formed from the cavity (52) passing through an outlet mouth (55) of the mold (50) aligned in a linear direction Z with the inlet mouth (54); characterized in that it also comprises the steps of: h) moving a plurality of shaping stops (56) of the mold (50), each provided with at least one concave curved surface (S2) in the shape of an inverted conical section arranged laterally around the cavity (52), from a retracted position , to be able to insert the plate (P) to be formed in the cavity (52), up to a stop position towards the inside of the cavity (52); m) press by means of the aforementioned concave curved surfaces (S2), the outer part of the box (B) including the four corner zones thereof, towards the inside of the cavity (52), against respective corner zones of the male ( 60) that each include a convex curved surface (62a ') with an inverted conical section shape, complementary to a respective concave curved surface (S2), each convex curved surface (62a') being arranged between two flat lateral sides ( 62) contiguous inclinations of the male (60); x) molding each of the four box corner areas (ZB) contiguous to two side walls (PL) of the box (B), creating a plurality of essentially linear wrinkles (AL) with each other in the box corner areas (ZB) during steps h) and / or m), this plurality of wrinkles (AL) providing an essentially curved surface with an inverted conical section shape in the box corner areas (ZB); k) moving the shaping stops (56) from their stop position to the retracted position to allow stage g) of evacuating boxes (B) without interfering with the shaping stops (56), after steps m) and x); w) Move a thrust member (16) in a controlled manner according to the linear transport direction X, by means of a rotary motor (12) and a rotational encoder (13) coupled to the rotary motor (12), to move the plate (P) from the stage y) controlled; Y u) depositing dots or strands of glue (CC), preferably hot, to carry out at least step c), this deposition being a function of the position of the push member (16) according to the controlled movement of step w). [17] 17. - The method according to claim 16, wherein, after stage z), lacks the steps of moistening the plate, and heating the concave curved surfaces (S2) and / or convex (62a 'to a working temperature) ), above the humidity and ambient temperature conditions where the machine is located (100). [18] 18. - The method according to claim 17, wherein said working temperature corresponds to that necessary to melt an adhesive, and preferably hot glue. [19] 19. - The method according to claims 16, 17 or 18, further comprising step l) of immobilizing the concave curved surfaces (62) of the shaping stops (56) in their respective stop positions. [20] The method according to claims 17 and 19, wherein step m) further comprises pressing two opposite side walls (PL) attached to the bottom portion (F) of the box (B) against two flat side sides (62) of the male (60) mutually opposite, by means of two flat lateral support faces (C4) of the mold (50) mutually opposite and with respective inclinations with respect to the linear direction Z, movable between retracted and stop positions, and each one of them arranged between two concave curved surfaces (S2). [21] 21. The method according to any one of claims 16 to 20, wherein: the die-cut plates (P) from which the boxes (B) are formed are made of corrugated cardboard, the corrugated cardboard comprising at least one smooth sheet and a corrugated sheet provided with corrugated undulations (OA), these sheets being adhered to each other ; In molding step x), the plurality of essentially linear wrinkles (AL) are essentially parallel or perpendicular to the direction of the grooved corrugations in the box corner areas (ZB). [22] 22. The method according to claim 21, wherein the plurality of essentially linear wrinkles (AL) are essentially parallel to the direction of the fluted undulations. [23] 23. The method according to any one of claims 16 to 22, wherein the molding step x) lacks the step of folding and overlapping portions of the corner area of the box (B) so that in these portions the The thickness of the lateral contour of the box (B) is equal to or greater than three times the thickness of the previously punched plate (P). [24] 24. - The method according to any one of claims 16 to 23, further comprising the steps of: d) apply points or cords of hot glue (CC) on overlapping portions (A) of outer flanges (R) located in the upper part of the lateral sides (CL) of the box (B) formed, to join some flanges (R) with the others; f) bending the four flanges (R) towards the outside of the box (B), by means of a male bending device mounted on a rear side (63) of the male (60); i) receiving on the upper end faces (58, 59) of the forming stops (56) the pressure of at least two flanges (R) previously bent in step f), with the male (60) in the position of maximum introduction ; j) pressing superiorly by contacting the overlapping portions (A) of the edges (R) located in the corner areas of the box (B) and previously bent towards the outside of the same, and gluing these edges (R) one with the others by pressure in these overlapping portions (A) by means of the hot glue (CC) previously deposited in stage d), this pressed and glued being executed with the bottom (F) of the box (B) stopped and the male (60) inserted into the box (B) in the position of maximum introduction; Y after steps h), i) and j), execute step k). [25] 25. - The method according to claims 19 and 24, further comprising step v) of immobilizing the upper end faces (58, 59) of the shaping stops (56) in the respective stop positions. [26] 26. - Cardboard box (B), formed from a previously punched flat plate (P) with cut lines and weakened fold lines, the box (B) comprising: a bottom (F); four lateral sides (CL) facing two by two surrounding the bottom (F); four corner zones, each one arranged between two respective contiguous lateral sides (CL); two opposite side walls (PL) each one attached to the bottom (F) by means of a respective fold line (LF), and members of two of the side sides (CL); glue (CC), preferably hot, applied directly or indirectly joining some lateral sides (CL) with others; characterized because Each of the four box corner areas (ZB) adjacent to two side walls (PL) of the box (B), are molded by creating a plurality of essentially linear wrinkles (AL) with each other in the corner areas of box (ZB), by means of a forming machine (100) equipped with a mold (50) with a cavity (52) facing a male (60) linearly movable through a cavity (52) with a mouth of Inlet (54) of plate (P) and an outlet mouth (55) of box (B) formed aligned, this plurality of wrinkles (AL) creating an essentially curved surface in the corner areas of box (ZB). [27] 27. - Box (B) according to claim 26, intended to be nested, wherein the four lateral sides (CL) facing two by two surrounding the bottom (F) have respective inclinations with respect to the bottom (F), and the essentially curved surface of each box corner zone (ZB) is shaped like an inverted conical section. [28] 28. - The box (B) of claim 26 or 27, further comprising at least four edges (R) parallel to the bottom (F), located at the top of each side side (CL) and folded outward from the box (B), which define four overlapping portions (A) of flange, one associated with the upper part of each corner zone of the box (ZB) that join the at least four flanges (R) to each other, these portions having overlapping flange (A) respective applied at least one point or bead of hot glue (CC) joining one end of a respective flange (R) with another. [29] 29. - The box (B) of claims 27 and 28, wherein: - two of said at least four edges (R) are each located in respective upper parts of the two side walls (PL), folded with respect to a respective bending line of the edge (LR) preferably towards the outside of the box ( B); - four corner panels (PZ) arise laterally from both ends of these two side walls (PL) to define the respective corner areas of the box (ZB); - a side flap (SL) is laterally adjacent to each corner panel (PZ); - four other edges (R) each arise from the upper part of each side flap (SL) in the flat development of the die-cut plate (P); Y - In said four overlapping portions (A) of the flange, the at least one point or bead of hot glue (CC) join one end of a respective flange (R) originating from the side walls (PL) with an end of a respective flange (R) arising from the side flaps (SL); Y - each of the other two lateral sides (CL) are formed from the at least partial overlap of one lateral flap (SL) with the other (SL) by means of points or cords of hot or cold glue (CC), and also optionally by another side wall (PL) attached to the bottom (F); Y the upper part of each of these other two lateral sides (CL) comprises an auxiliary overlap portion (AX) between flanges (R) arising from the lateral flaps (SL) having applied at least one point or tail cord (CC ) hot. [30] 30. The box (B) of claims 27 and 28, wherein: - four of the aforementioned at least four edges (R) are each located in respective upper parts of four side walls (PL) attached to respective sides of the bottom (F) by means of respective fold lines (LF), and bent with respect to a respective lip fold line (LR) preferably towards the outside of the box (B); - four corner panels (PZ) arise laterally from both ends of these two side walls (PL) to define the respective corner areas of the box (ZB); - a side flap (SL) is laterally adjacent to each corner panel (PZ); - in the aforementioned four flange overlapping portions (A), the at least one point or bead of hot glue (CC) join the flange ends (R) emerging from the side walls (PL) with each other; Y - each of the other two lateral sides (CL) are formed from the overlap of both lateral flaps (SL) by means of respective points or cords of hot or cold glue (CC) with another lateral wall (PL) attached to the bottom (F ); Y - four reinforcing flaps (SR) originating at the bottom from some lateral bends (E) of the flanges (R) on both sides of two opposite side walls (PL), they are joined with at least one point or tail cord (CC) hot to respective corner area of the box (ZB). [31] 31. The box (B) of claim 30, wherein each lateral bend (E) has bend portions (E1, E2, E3) with curved shape, finished in an overlap end portion (E3) substantially parallel in the flat development of the plate (P) to the end portion of the other joining flange (R). [32] 32. The box (B) of claim 30 or 31, further comprising four other reinforcing flaps (SR), joined with glue (CC) to respective corner area of the box (ZB), arising from the bottom of the lateral bends (E) of the flanges (R) on both sides of two opposite side walls (PL). [33] 33. The box (B) according to any one of claims 30 to 32, further comprising four other reinforcing flaps (SR), joined with glue (CC) to respective lateral ends of the lateral walls (PL), originating from below the lateral bends (E) of the flanges (R) on both sides of two opposite side walls (PL). [34] 34. The box (B) according to any one of claims 26 to 33, wherein the cardboard is corrugated cardboard, with at least one smooth sheet and one corrugated sheet provided with corrugated undulations (OA), these sheets being adhered to each other, and the plurality of essentially linear wrinkles (AL) being essentially parallel or perpendicular the direction of the grooved undulations (OA) in the box corner areas (ZB).
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同族专利:
公开号 | 公开日 ES2839552R1|2021-09-03|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题 BE603605A|1961-05-10|1961-09-01|Al Foerpackning Ab|A method and a stamping tool for the manufacture of dose packages made of sheet material and the package obtained.| GB1490301A|1974-04-16|1977-11-02|Machida Shigyo Co Ltd|Manufacturing containers by folding blanks| US4295839A|1979-07-06|1981-10-20|Kliklok Corporation|Method and apparatus for forming a flanged tray| US4522618A|1982-04-08|1985-06-11|Sprinter Systems Incorporated|Mechanism for assembling tapered, nested containers| JP3448435B2|1996-07-01|2003-09-22|東洋アルミホイルプロダクツ株式会社|Paper container and method of forming paper container| ES1073027Y|2010-06-25|2011-02-08|Boix Maquinaria Sa|MACHINE TO ASSEMBLE CARTON BOXES| MX2015005233A|2012-10-25|2015-11-16|Int Paper Co|Apparatus and methods for folding paper boxes.| ES2593823B1|2015-06-08|2017-09-19|Telesforo Gonzalez Maquinaria Slu|Machine forming bases or covers of prismatic boxes by folding and joining of die-cut plates|
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