BR112019007562B1 - FLUID BAG AND METHOD FOR MANUFACTURING A FLUID BAG - Google Patents

Abstract

A fluid bag comprises: a first skin (1100) and a second skin (1200) connected to each other by means of a tighter seal (1300) and a weaker seal (2700) so as to form a cavity (1500) for a fluid, the cavity (1500) having a perimeter and said perimeter comprising at least a part of the stronger seal (1300) and at least a part of the weaker seal (2700), and wherein the weaker seal (2700) is in the vicinity of the strongest seal (1300).

Description

field of invention

[0001] The present invention generally relates to the field of bags for containing fluids. In particular, the invention relates to an improved fluid bladder, which improves bladder opening and/or fluid leakage.

Background of the invention

[0002] Various patents, patent applications and publications are cited in this description in order to more fully describe the state of the art to which this invention belongs. The complete description of each of these patents, patent applications and publications are incorporated herein by reference.

[0003] Fluid pouches made by sealing two films, or layers, or multilayers, together are known in the art. They are generally obtained by overlapping two sheets or films, for example made of polymeric material, and sealing them together with a seal (“seal”), so as to form a cavity which is filled with the fluid. The seal is generally formed by the simultaneous application of heat and pressure so as to at least partially fuse the two sheets together. By breaking the seal it is possible to pour the fluid when desired.

[0004] Referring now to the drawings, similar reference numerals designating corresponding structures in all views, and referring in particular to Figures 1A and 1B, a front view of a bag 1000, according to prior art, is illustrated schematically. Pouch 1000 is made by layering films 1100 and 1200 on top of each other and performing a seal 1300 by sealing the film 1100 with the film 1200. The seal 1300 defines a cavity 1500 which can be filled with a fluid 1600. In Figure 1A, fluid 1600 is illustrated as not completely filling cavity 1500. However, it is also possible to completely fill cavity 1500 with fluid 1600.

[0005] The pouch 1000 further comprises an opening structure 1400, illustrated here in the form of a pre-cut section of one or both of the films 1100, 1200. In particular, the opening structure may comprise holes in one or more, or all of the layers of films 1100 and/or 1200. The aperture structure 1400 facilitates tearing of the films 1100 and/or 1200 along the aperture structure 1400. A user can thus tear the films 1100, 1200 along of the aperture structure 1400, thereby achieving the aperture seal 1300, as illustrated in Figure 1B. At this point, the cavity 1500 is in communication with the external environment and the fluid 1600 can be poured outside the bag 1000.

[0006] However, such a device has several disadvantages.

[0007] Firstly, when opening the pouch 1000, the user generally has to apply force to cut through the seal 1300. To do this, the user grips the pouch and thereby presses to some extent into the cavity 1500. Consequently, it may happen that the fluid 1600 inadvertently leaks out of the opening created by the rupture of the seal 1300, once the seal 1300 opens, due to the pressure applied by the user. This creates the risk that fluid 1600 could stain the user's hands and/or clothing and/or inadvertently spill out of the intended container.

[0008] Furthermore, after the tear has passed through the seal 1300 it will reach an opening portion 1001. If the bag 1000 was previously positioned upside down, or if pressure was previously applied on the bag 1000, the opening portion 1000 opening 1001 will contain a certain amount of fluid 1600. In this case, even if very careful, it is difficult for the user to prevent fluid 1600 from coming into contact with his fingers.

[0009] Additionally, cutting through the seal 1300 can be difficult. As the seal 1300 is designed to be quite strong in order to withstand accidental pressure applied to the cavity 1500, in some cases the user may become frustrated by repeatedly trying to cut through the seal 1300. Since the seal 1300 must provide such secure seal on itself, it is not possible to reduce the sealing strength of the seal 1300 so that its opening is facilitated.

Summary of the invention

[0010] The aforementioned problems are solved by teaching the independent claims.

[0011] The present invention generally exploits the advantage of providing two weldments having two different seal lengths, in a manner that solves at least some of the aforementioned problems.

[0012] In particular, the stronger seal is arranged around the weaker seal in such a way that accidental opening of the pouch is not possible. Additionally, once the tighter seal is opened, fluid leakage can still be prevented by the weaker seal, which can be opened by the user applying pressure to the bag. In this way, the user has more control over fluid spillage such that accidental spillage, or leakage, can be prevented.

[0013] Furthermore, it can also provide the advantage that the strongest seal, or parts thereof, can be made smaller or weaker than in the prior art, since the seal can be provided by combining the strongest seal and the weakest, on the contrary, only by the strongest sealing as in the previous technique. By allowing a stronger or weaker or smaller seal, the invention provides the added advantage that it may be easier for the user to open the stronger seal.

[0014] The last advantage, i.e. the potential reduction in the required opening force, in turn, can further reduce the force the user applies to open the bag, thereby further reducing the risk of fluid spillage or leakage .

[0015] In general, the advantageous combination of two welds with two different sealing strengths between the cavity and the outside of the bag solves the aforementioned problems associated with the prior art.

[0016] The advantages and features of novelty that characterize the invention are particularly pointed out in the appended claims that form part of the present application. For a better understanding of the invention, its advantages, and the objects obtained by its use, however, reference should be made to the drawings which form a further part thereof, and to the accompanying descriptive matter, in which it is illustrated and described in one or more preferred embodiments of the invention.

[0017] Referring now to Figures 2 to 11, there is disclosed a fluid bag comprising: - a first film 1100 and a second film 1200 connected to each other by means of a tighter seal 1300, 5301-5303, 6300 , 7300, 8300, 9300 and a weaker seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 17001 to form a cavity 1500 for the fluid, the cavity 1500 having a perimeter comprising at least at least a part of the stronger seal 1300, 5301-5303, 6300, 7300, 8300, 9300 and at least a part of the weaker seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700, characterized by the fact that that the weakest seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 is in close proximity to the strongest seal 1300, 5301-5303, 6300, 7300, 8300, 9300.

[0018] Preferably, in the bag of the present invention, the weakest seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 and the strongest seal 1300, 5301-5303, 6300, 7300, 8300, 9300 are configured such that the weakest seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 can only open if at least a first part of the strongest seal 1300, 5301-5303, 6300, 7300, 8300, 9300 is opened or removed.

[0019] More preferably, the pouch of the present invention further comprises an opening structure 1400, the opening structure 1400 being configured to facilitate the opening of the first film 1100 and/or the second film 1200 at least along of a first length, the first length traversing at least the first part of the strongest seal 1300, 5301-5303, 6300, 7300, 8300, 9300.

[0020] Optionally, the opening structure 1400 comprises points, perforations, and/or weakening holes made in the first film 1100 and/or in the second film 1200. Preferably, the opening structure 1400 is configured to facilitate cutting of the first film 1100 and/or the second film 1200 so as to leave at least a portion of the weaker seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 exposed to the environment.

[0021] The weakest seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 of the pouch of the present invention has a length 2701 equal to or less than 50 mm, preferably equal to or less than 30 mm, even more preferably equal to or less than 10 mm and/or a width 2702 equal to or less than 5 mm, preferably equal to or less than 3 mm, even more preferably equal to or less than 1 mm .

[0022] In the pouch of the present invention, the first skin 1100 and/or the second skin 1200 may comprise any material suitable for containing the filler 1600. However, preferably, the first skin 1100 and/or the second skin 1200 comprises a mixture of ionomer and polypropylene.

[0023] Preferably, the strongest seal 1300, 53015303, 6300, 7300, 8300, 9300 of the bag of the present invention has a seal strength above 15N/15 mm, more preferably above 40N/15 mm. Also preferably, the weakest seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 of the pouch of the present invention has a seal strength of 1-8N/15 mm, more preferably 2-3N /15 mm.

[0024] Also described herein is a method for manufacturing a fluid pouch, the method comprising the steps of: - providing a first film 1100 and a second film 1200, - connecting the first film 1100 and the second film 1200 to each other in an so as to form a cavity 1500 for the fluid by performing a stronger seal 1300, 53015303, 6300, 7300, 8300, 9300 and a weaker seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 , characterized in that the weakest seal 2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700 is made in the vicinity of the strongest seal 1300, 5301-5303, 6300, 7300, 8300, 9300.

Brief description of the drawings

[0025] Figures 1A and 1B schematically illustrate a front view and an enlarged view of a bag 1000 according to the prior art;

[0026] Figures 2A, 2C and 2E schematically illustrate a front view of a pouch 2000, in accordance with an embodiment of the invention. Figures 2B, 2D and 2F schematically illustrate an enlarged view of Figures 2A, 2C and 2E, respectively;

[0027] Figures 2G and 2H schematically illustrate a cross-sectional top view of the pouch 2000, respectively, of Figures 2B and 2F;

[0028] Figures 3a and 3b schematically illustrate a front view and an enlarged view of a bag 3000 according to an embodiment of the invention;

[0029] Figures 4A, 4C and 4E schematically illustrate a front view of a pouch 4000, in accordance with one embodiment of the invention. Figures 4B, 4D and 4F schematically illustrate an enlarged view, respectively, of Figures 4A, 4C and 4E;

[0030] Figures 5A to 5C schematically illustrate enlarged views of pockets 5001-5003, according to embodiments of the invention;

[0031] Figure 6 schematically illustrates a front view of a bag 6000, according to an embodiment of the invention;

[0032] Figure 7 schematically illustrates a front view of a bag 7000, according to an embodiment of the invention;

[0033] Figure 8 schematically illustrates a front view of a bag 8000, according to an embodiment of the invention;

[0034] Figure 9 schematically illustrates a front view of a bag 9000, according to an embodiment of the invention;

[0035] Figure 10 schematically illustrates a front view of a bag 10000, according to an embodiment of the invention; and

[0036] Figure 11 schematically illustrates a front view of a pouch 11000, in accordance with an embodiment of the invention.

Detailed description of the invention

[0037] In the following, various embodiments are described with reference to the drawings. However, it should be understood that the present invention is not limited to any specific embodiment, but is rather defined by the claims, and the embodiments are provided for a better understanding thereof. Furthermore, although each embodiment may be described as comprising various features, it should be understood that not all features described for each embodiment are essential for implementing the specific embodiment, or for implementing the present invention. Additionally, it will be understood that the features of the different embodiments can be combined in order to realize alternative embodiments, within the scope of the claims.

first realization

[0038] Figures 2A, 2C and 2E schematically illustrate a front view of a pouch 2000 in accordance with an embodiment of the invention. Figures 2B, 2D and 2F schematically illustrate an enlarged portion of Figures 2A, 2C and 2E, respectively.

[0039] As can be seen in Figure 2A, the bag 2000 comprises a first film 1100 and a second film 1200 connected to each other by two seals 1300 and 2700. In particular, the first film 1100 and the second film 1200 overlap each other another so that when the seals 1300 and 2700 are made, a cavity 1500 can be formed between them.

[0040] For the purposes of the present invention, the first and second polymeric films used to make the sidewalls of the bag, in principle, can both be of a single-layer or multi-layer polymeric film. The film involved in the construction of the side walls does not necessarily have to have the same structure (for example, one layer can be clear and the other can be opaque). Furthermore, in principle, any such film-grade polymeric resin or material, as generally known in the packaging art, can be employed. Preferably, a multilayer polymeric film structure is employed. Typically, the multilayer polymeric film will involve at least three categorical layers, including, but not limited to, an outermost structural or abuse layer, an inner barrier layer, and an innermost barrier layer. and, optionally, one or more binding or adhesive layers therebetween. In addition, the innermost layer making contact with and compatible with the intended contents of the pouch is preferably capable of forming both perimeter closure seals (i.e., the strongest seal of the invention with seal forces typically greater than 20 N /15 mm) and the weakest seal(s). More preferably, the innermost layer is also heat sealable.

[0041] The outermost breaching or structural layer is typically oriented polyester or oriented polypropylene, but may also include nylon or oriented paper. This layer is preferably reverse printed and advantageously unaffected by the sealing temperatures used to make the pouch, as the pouch is sealed through the full thickness of the multilayer structure. The thickness of this layer is typically selected to control the stiffness of the bag, and can range from about 10 to about 60 [mu]m, preferably about 50 [mu]m.

[0042] The inner layer may include one or more barrier layers, depending on what atmospheric conditions (oxygen, moisture, light, and the like) may potentially affect the product contained in the bag. The barrier layers can be metallized oriented polypropylene (PP) or oriented polyethylene terephthalate (PET), ethylene vinyl alcohol (EVOH), aluminum foil, nylon or biaxially oriented nylon, blends or composites thereof, as well as related copolymers of the same. The thickness of the barrier layer will depend on the sensitivity of the product and the intended shelf life.

[0043] The innermost layer of the package is the sealant. The sealant is selected to have a minimal effect on the flavor or color of the contents, to be unaffected by the product, and to resist sealing conditions (such as liquid droplets, grease, dust, or the like). The sealant is typically a resin, which can be bonded to itself (sealed) at temperatures substantially below the melting temperature of the outermost layer so that the appearance of the outermost layer will not be affected by the sealing process and will not adhere on the sealing bar jaws. Typical sealants used in multilayer pouches include ethylene copolymers such as low density polyethylene (LDPE), linear low density polyethylene (LLDPE), metallocene polyethylene (mPE), ethylene vinyl acetate copolymers or methyl acrylate, or copolymers of ethylene acrylic acid (EAA) or methacrylic acid (EMAA), optionally ionomerized (i.e. partially neutralized to form carboxylate salts with metal ions such as Na, Zn, Mg, or Li cations ). Typical sealants may also include polypropylene copolymers. Sealing layers are typically 10 to 100 µm thick. For the present invention, the sealant must be able to form a side compartment that will rupture and burst upon pressure, i.e., at the weakest seal.

[0044] Preferably, the weaker seal is formed by heat sealing two superimposed multilayer polymeric films each having the innermost sealing layer made from a resin, which undergoes interfacial peeling of the seal having different strengths of seal when heat seals are formed at different temperatures. Such resins include blends of one or more polyolefins, such as: polyethylene, including metallocene polyethylene with polybutylene or polypropylene including homopolymer or copolymers thereof (collectively: PE/PB blends; PE/PP blends); polypropylene with polybutylene (PP/PB blends); polypropylene with ethylene methacrylic acid copolymer (PP/EMAA blends); or polypropylene with styrene-ethylene/butylene-styrene block terpolymer (PP/SEBS blends). Alternatively the weaker seal can be produced by coating the innermost layer zone in the region of the seal with a sealant. Alternatively, the weaker seal can be formed by heat sealing two different sealing surfaces, such as an ethylene ionomer copolymer. Particularly preferred are mixtures of an ionomer based on the partial neutralization of an ethylene acrylic acid copolymer or ethylene methacrylic acid copolymer with a polypropylene α-olefin (EAA or EMAA ionomer mixed with a PP/PB copolymer) as the layer of more internal sealing, since the other mixtures are less reliable and the zone coating is more expensive. Such ionomer with polypropylene copolymer blends, exhibiting predictable peel resistance over an extended heat seal temperature range, are described in US Pat. 4,550,141, 4,539,263, 4,469,754 and European Patent EP 1,751,231.

[0045] In order to manufacture a weaker seal containing at least one-half concentration strength to selectively exceed the seal strength of the weaker seal, several alternative methodologies are contemplated. Preferably, the weakest shape and/or curvature of the seal is to be used to advantageously concentrate the forces created when the package is manually compressed or squeezed. However, when zone heat sealing resin coverage is employed, intentionally reducing the width of the zoned coating or the like along the weakest seal can also be advantageously employed as a means of concentrating strength for the purpose of exceeding selectively seal strength (with or without bending). In addition, the variable geometry and/or width of the (heated) heat seal bar employed to heat seal, the weaker seal can be utilized to produce a force concentration means useful in the present invention. In principle and in fact, time and temperature sealing methods can also be employed to make a weaker seal containing a force concentrating medium to selectively exceed the seal strength of the weaker seal. For example, but not by way of limitation, repetitive and/or multiple tapping of different heat seal bars can produce a weaker seal with varying seal strength which then serves as a structure equivalent to the claimed force concentration means for selectively exceed the seal strength of said weakest seal.

[0046] For the purposes of measuring the sealing strength mentioned above, samples of the polymeric film of 100 mm by 15 mm are to be cut with the longer side of the samples in the machine direction of the film. Enough film samples are cut to provide a set of three samples for each heat seal condition. The films are then folded so that the sealing layer on each side contacts the other. The film is then heat sealed between the heat sealer jaws at the appropriate temperature, time and pressure. Heat-sealed samples are then conditioned for at least 24 hours at 23°C and 50% relative humidity prior to testing. The folded portion of the sealed film is cut in half, forming flaps suitable for placement on the Instron Jaw Clamps. 15 mm wide samples are then cut in the film machine direction to provide at least three 15 mm wide test samples under each set of sealing conditions.

[0047] The seal strength is measured by pulling the seals apart at an angle of 180° in the direction of the film machine using the Instron tensile testing machine at the mordant separation speed of 100 mm/minute. In other cases, a pull rate of 300 mm/minute on Instron may also be employed. The maximum force required to cause the seal to fail is then recorded and the average of at least three samples is reported in N/15 mm. The seal strength is measured at room temperature.

[0048] Other particularly preferred blends of polymers for use as the weakest seal forming the innermost layer include a combination of an ethylene vinyl acetate (EVA) copolymer or acid modified EVA copolymer and an ethylene vinyl acetate (EVA) copolymer and an ethylene vinyl acetate (EVA) copolymer. methyl) (EMA) or acid-modified EMA as the major component and a polypropylene homopolymer or copolymer, a polybutylene homopolymer or copolymer, a partially neutralized ethylene acid ionomer or metallocene polyethylene ionomer blend as the minor component. Such polymeric systems and blends are commercially available as sealants from E.I. du Pont de Nemours & Company under the trade names Appeel(R), Bynel(R), Elvax(R), Nucrel(R) and Surlyn(R). Again, various additives are often employed, including, by way of example, but not limited to, slip, non-stick, and/or chill roll release agents and the like. Using these EMA and acid-modified EVA based blends in combination with various other layers of polymeric films, the heat seal strength can selectively range from 5 N/15 mm up to 50 N/15 mm with a seal strength by heat of locking in excess of 15-20N/15 mm.

[0049] During the manufacture of the polymeric film sheet to be used in making the bag, coextrudable adhesives are optionally used between the functional layers to adhere one layer to the other and to provide structural integrity. These include, but are not limited to, ethylene or propylene polymers and copolymers modified with or grafted with unsaturated carboxylic acid groups such as a maleic or maleic anhydride and the like. In addition, to provide additional thickness (if desired by the consumer for a particular application), polyolefin bulk layers or multilayer film remnants trimmed during bag manufacture may be incorporated within the multilayer structure. It is contemplated that the polymeric film sheet (i.e., so-called "web stock") may be produced using any combination of processes generally known in the art, such as monolayer or multilayer casting, blown film, , extrusion lamination, and adhesive lamination and combinations thereof. Processing aids, as generally known in the art, including, by way of example, but not limited to, glidants (such as amide waxes), antiblocking agents (such as silica), and antioxidants (such as , hindered phenols), can be incorporated into the roll material if necessary to facilitate either film making or pouch formation. Pouches are formed from the roll material either by heat sealing and cutting separate pieces of the roll material or by a combination of heat sealing and folding with cutting. Bag making equipment such as that made by Totani Corporation, Kyoto, Japan or Klockner Barlelt Co., Gordonsville, Va., can be advantageously used in the practice of this invention. The frangible compartment can be installed either during or after bag formation. It should further be appreciated that the heat-sealed perimeter of the pouch in accordance with the present invention can be obtained by superimposing the first and second sheets of polymeric film and then heat sealing each directly to the other or by heat sealing each other. heat them indirectly through the use of a third intervening polymeric film, again as is generally known and practiced in the art.

[0050] Preferably, the sealing film is made of a polymer system that can show sealing strength above 15N/15 mm at sealing temperatures above 150°C and sealing strength values of 3-10N/15 mm at sealing temperature range 100-140°C.

[0051] Returning to Figures 2A-2F, the first and second plies 1100, 1200 are connected to each other by means of a stronger seal 1300 and a weaker seal 2700 to form the cavity 1500 for the fluid 1600. The stronger seal 1300 differs from the weaker seal 2700 at least in its seal strength. In particular, the stronger seal 1300 has a first seal strength and the weaker seal 2700 has a second seal strength less than the first seal strength. Even more specifically, the tightest seal 1300 is such that the films 1100, 1200 cannot be separated once the seal is formed. Less preferably, the films 1100, 1200 can be separated since the seal is formed by an internal rupture, for example, a delamination between an outer layer and a barrier layer, which is internal to one or both of the films 1100, 1200. On the other hand, the weaker seal 2700 can be delaminated by applying pressure. That is, the two films 1100, 1200 can be separated from one another in the weakest seal region 2700 by applying pressure to the cavity 1500 and/or pulling the two films 1100, 1200 apart.

[0052] Typically, the weakest seal 2700 has a seal strength of 1 to 8 N/15 mm, preferably 2 to 3 N/15 mm, and the strongest seal 1300 has a seal strength above 15 N/15 mm. 15 mm and preferably less than 40N/15 mm.

[0053] In an exemplary embodiment, the weakest seal 2700 has a length 2701 equal to or less than 50 mm, preferably equal to or less than 30 mm, even more preferably equal to or less than 10 mm . In this embodiment, the weaker seal 2700 also has a width equal to 2.702 or less than 5 mm, preferably equal to or less than 3 mm, even more preferably equal to or less than 1 mm. The stronger seal 1300 preferably has a width of approximately 5 mm and a variable length.

[0054] Typically, the weakest seal 2700 can be made by applying a heat of approximately 100-130°C to the seal for 1 second at 3 bar. Typically, the stronger seal 1300 can be made by applying a temperature preferably greater than 150°C and/or preferably less than 200°C for 1 second at 3 bar, when a temperature variable, resistance variable of sealant seal is selected.

[0055] As seen in Figure 2A, and better understood with reference to the enlarged view in Figure 2B, the cavity 1500 has a perimeter that is defined by, or comprises, at least part of the strongest seal 1300 and at least part, of the weakest seal 2700. In this specific embodiment, the perimeter of the cavity 1500 is defined by the entire length of the weakest seal 2700, i.e., between points A and B, and by part of the strongest seal 1300, i.e. , through the part between points A and B, where points A and B are the points of contact between the two seals. Here and below, when reference is made to a distance along a perimeter between a first and second point, the distance is measured from the first point and moving clockwise along the perimeter to the second point.

[0056] Furthermore, as best seen in Figure 2B, the weakest seal 2700 is in close proximity to the strongest seal 1300. Even more specifically, in this specific embodiment, the weakest seal 2700 is in contact with the strongest seal 1300 on three of its sides. Even more specifically, the weaker seal 2700 is in contact with the stronger seal 1300 on all of its sides not facing the cavity 1500. Stated another way, the perimeter portion of the weaker seal 2700, between points A and B, defines the perimeter of the cavity 1500 and is not in contact with the strongest seal 1300, while the perimeter portion of the weakest seal 2700, between points B and A, is not facing the cavity 1500 and is in contact with the strongest seal 1300. In this manner, the pouch opening through the opening structure 1400 traverses both the strongest seal 1300 and the weakest seal 2700.

[0057] However, it will be understood that the present invention is not limited to this embodiment, and that alternative configurations of stronger and weaker sealing can be implemented as will be described below. More generally, any configuration of the strongest seal 1300 and the weakest seal 2700 may be implemented that allows the cavity 1500 to be defined and that prevents fluid 1600 from escaping from the cavity 1500 since both the strongest seal 1300 and the closest seal weak 2700 are open. For example, embodiments are described where some parts or the entire perimeter of the weaker seal 2700 between points B and A are not in contact with the stronger seal 1300.

[0058] As can be seen in Figures 2C and 2D, when the pouch 2000 is opened by tearing the first film 1100 and the second film 1200 along the opening structure 1400, the contents of the cavity 1500 are advantageously not immediately exposed to the outer side of the pouch 2000 due to the presence of the weaker seal 2700. Rather, at least a portion of the weaker seal 2700, as visible in Figure 2D, prevents fluid 1600 from escaping from the cavity 1500. In this way, the fluid 1600 can be prevented from leaking over the user's fingers and/or from inadvertently being spilled outside the bag 2000 during the opening of the bag 2000 or, more generally, from reaching the outside of the bag 2000, in a moment when the user does not want fluid to escape from cavity 1500.

[0059] As seen in Figures 2E and 2F, once the user applies moderate pressure to the cavity 1500 the weaker seal 2700 opens, under the effect of the pressure applied by the fluid 1600, and allows the fluid 1600 to escape from the cavity 1500. Alternatively, this can be achieved by pulling the films 1100, 1200 away from each other. In this way, the user can advantageously control the moment at which the fluid 1600 will be poured out of the bag 2000 and thus prevent the accidental spillage of the fluid 1600.

[0060] It should be understood that, in the Figures, the weakest seal portion 2700 illustrated as not being present, represents a weakest seal portion 2700 that has been delaminated and opened. The illustration is not intended to imply that any material is removed from the plies 1100, 1200 or from the weaker seal 2700. This configuration is further illustrated in Figures 2G and 2F, which represent a cross-sectional top view of the bag 2000 of Figures 2B and 2F, respectively. In particular, the cross section is taken at substantially the Y position of the aperture structure 1400. As seen in Figure 2G, the seals 1300 and 2700 are both closed and thus keeping the films 1100, 1200 sealed together. Rather, as visible in Figure 2F, the weaker seal 2700 is still present, but it has delaminated, thus allowing fluid 1600 to pass through. This delaminated portion is illustrated in Figures 2E and 2F by removing the corresponding portion of the weakest seal 2700.

[0061] Referring now to Figure 2B, in some embodiments, at least the portion 1301 of the strongest seal 1300 can be made smaller and/or weaker than in the prior art. In particular, due to the presence of the weaker seal 2700, at least at the end of the portion 1301 through which the opening structure 1400 directs the tear, it can be made smaller and/or weaker. Since part 1301 is cooperating with weaker seal 2700 in preventing fluid 1600 from escaping cavity 1500, it may not be necessary to make as strong a seal 1300 as in the prior art. This provides the further advantage that the opening of the part 1301 is facilitated compared to the prior art. Therefore, the user has to exert less force when opening the bag 2000 and the overall opening process is rendered simpler and more accessible to a wider audience of users, such as children and elderly people.

Second embodiment (general concept: the weakest seal and the strongest seal need not be in contact with each other around the entire perimeter of the weakest seal from point A to B for the invention to work)

[0062] Figures 3A and 3B schematically illustrate a front view of a bag 3000 according to another embodiment of the invention, which further clarifies how the two seals can be, in some embodiments, considered to be in close proximity to each other without the entire perimeter from B to A of the weaker seal 2700 being in contact with the stronger seal 1300, as is the case in the previous embodiment. In particular, the pouch 3000 differs from the pouch 2000 in that the weaker seal 3700 is not in contact with the stronger seal 1300 at least in the part of its perimeter comprised between points C and D.

[0063] Also in this case, the perimeter of the cavity 1500 is defined by a part of the strongest seal 1300 and the weakest seal 3700, as in the bag 2000. That is, the cavity is defined by the perimeter of the weakest seal 3700 between A and B, along with the perimeter of the stronger seal 1300 between A and B. Furthermore, in the present embodiment, the weaker seal 3700 can be considered to be in close proximity to the stronger seal 1300. More generally, the two seals 1300, 3700 can be considered in proximity as long as the weakest seal 3700 is not too far away from the strongest seal 1300, as would be the case, for example, if the weakest seal is placed in the middle of the cavity.

[0064] Even more specifically, the weakest seal 3700 has a perimeter P. Some points of the perimeter P face the cavity 1500 and thus define the perimeter of the cavity. In the illustrated examples, these points are between A and B. Additionally, some points of the perimeter P are in contact with the strongest seal 1300, such as the points between D and A, and between B and C. remaining points, specifically the perimeter points P not facing the cavity 1500 and not in contact with the strongest seal 1300, are within a predetermined distance from the strongest seal 1300. In the illustrated embodiment these points are those comprised between C and D. For example, point P1 of these last points is illustrated as an example. A circle centered on P1 and having a predetermined distance or radius D1 is illustrated to define an equidistance region centered on the point P1. As can be seen, at least a portion of the strongest seal 1300 is within the circumference. That is, the point P1 is within the predetermined distance D1 from the strongest seal 1300. When this condition is satisfied for all perimeter points P not facing the cavity 1500, such as the points between B and A, the two seals 1300 and 3700 can be considered to be in proximity within the meaning of the invention. In some embodiments, the predetermined distance D1 is less than 5 cm, preferably less than 2 cm, even more preferably less than 1 cm. In this approach, the two seals can be in close proximity to each other, without requiring seal 1300 to be in contact with all points of seal 3700 not facing cavity 1500.

[0065] This configuration can advantageously simplify the manufacture of the weaker seal 3700. In particular, since the weaker seal 3700 is not in contact with the stronger seal 1300 on its longer side, the risk of heat and pressure used to perform the strongest seal 1300 interfere with the weakest seal 3700 is reduced. That is, when the two seals are in contact with each other, the heat and pressure applied to achieve the stronger seal 1300 can also have an effect on the neighboring region of the weaker seal 3700. This can be less critical on parts weaker seal between points B and C and between points D and A, as these parts do not necessarily need to open for fluid to exit the bag 300. On the other hand, the part between points C and D can be problematic if manufacturing the stronger 1300 seal also resulted in a stronger seal than the weaker 3700 expected in this region. By leaving a small distance between these two seals, this problem is advantageously solved and the manufacture of the pouch 3000 is simplified.

Third embodiment (general concept: the weakest seal and the strongest seal may not be in general contact, but separated by a very small but still measurable distance, either desired or due to manufacturing tolerances)

[0066] Figures 4A and 4B schematically illustrate a front view and an enlarged view of a bag 4000 according to an embodiment of the invention, which further clarifies, as the two seals 1300, 4700 can be considered next to each other, although one small space is present between them.

[0067] Bag 4000 differs from bag 2000 in that the weakest seal 4700 is not in contact with the strongest seal 1300. Instead, a distance of up to D2, exaggerated in the drawings for ease of representation, is present between the two seals 1300, 4700. The distance D2 can be due, for example, to manufacturing tolerances and can be up to 3 mm, preferably up to 1 mm, even more preferably up to 0.5 mm. It should be understood that the distance between the two seals 1300, 4700 can vary from 0 to D2, so that, at least at some points, the two seals 1300, 4700 can actually be in contact with each other.

[0068] In this and other embodiments, even if the two seals are separated by the distance D2, they can be considered to be close to each other, while the weaker seal 4700 and the stronger seal 1300 are configured in such a way that the weaker seal 4700 can only open if at least a first part of stronger seal 1300 is opened or removed. In the specific illustrated embodiment, this is achieved by providing the stronger seal 1300 on all sides of the weaker seal 4700 not facing the cavity 1500, and will be better understood with reference to Figures 4C through 4F.

[0069] It should be noted that the parts of the films 1100 and 1200 within the distance D2 can be considered as sealed, for practical purposes. In particular, the tighter seal 1300 prevents the films 1100, 1200 from separating from each other in the seal region 1300 regardless of applied pressure. This effect also contributes to keeping the two films 1100, 1200 next to each other in the distance region D2, due to the immediate proximity of the stronger seal 1300, as well as the immediate proximity of the weaker seal 4700. that the perimeter of the cavity is further defined by a portion of the stronger seal 1300 and the weaker seal 4700, as these two seals also effectively seal the films 1100 and 1200 in the distance region D2 due to their close proximity of the same.

[0070] As seen in Figures 4C and 4D, when pressure is applied to the pouch 4000, either intentionally or accidentally, the weaker seal 4700 may begin to open. In particular, the opening begins at approximately the center of the weakest seal 4700, as this is the furthest position from the strongest seal 1300. More specifically, in the weakest seal regions 4700 closest to the strongest seal 1300, the films 1100 and 1200 are more difficult to separate compared to regions closer to the center of weaker sealing 4700, as the stronger sealing effect 1300 against separation of films 1100 and 1200 is reduced when the distance between the sealing is longer strong 1300 is increased.

[0071] Due to the presence of the strongest seal 1300 on all sides of the weakest seal 4700, other than the side facing the cavity 1500, it is possible to prevent the weakest seal 4700 from opening completely, even when the pressure is applied to cavity 1500. Furthermore, even in the presence of distance D2 between the two seals 1300, 4700, the films 1100 and 1200 are prevented from separating due to the combined action of the stronger and weaker seals 1300, 4700.

[0072] As can be seen from Figures 4E and 4F, only when the stronger seal 1300 is opened, or removed, can the weaker seal 4700 be opened completely. Specifically, in the illustrated embodiment, by removing at least some of the top portion of the stronger seal 1300, the weaker seal 4700 is no longer prevented from opening and the pressure exerted by the fluid 1600 can open the weaker seal 4700.

[0073] It should be understood that the shape of the strongest seal 1300 and the weakest seal 4700 illustrated in Figures 4A to 4F, are not the only ones that achieve the above-described effect. Any shape of the two seals 1300, 4700 that prevents the weaker seal 4700 from opening while the stronger seal 1300 is intact can be implemented. For example, Figures 5A to 5C illustrate various alternative embodiments for possible forms of stronger seals 5301, 5302 and 5303 and weaker seals 5701, 5702 and 5703 of pouches 5001, 5002, 5003. In all cases, the tighter seal weak seal 5701, 5702 and 5703 is in proximity to the stronger seal 5301, 5302 and 5303, such that the weaker seal 5701, 5702 and 5703 can only open if at least a first part of the stronger seal 5301, 5302 and 5303 is opened or removed. However, it will be understood that such forms of sealing can generally be used in any embodiment of the invention, for example in combination with the embodiments illustrated in Figures 2A and 3A.

[0074] In some embodiments of the invention, the aperture structure 1400 is configured to facilitate cutting the first film 1100 and/or the second film 1200 along a first length crossing at least the strongest seal 1300. length can be determined, for example, by extending the length of the aperture structure. For example, referring to Figure 2B, opening structure 1400 will direct the tear through portion 1301 of seal 1300, resulting in the tear illustrated in Figure 2D.

[0075] In some embodiments, the first length may also cross at least part of the weakest seal, as illustrated in Figure 2D relative to the weakest seal 2700. An advantage of this approach, as described above, is that part 1301 of the stronger seal 1300 can be made smaller since it is cooperating with neighboring weaker seal 2700 to hold plies 1100 and 1200 together. However, the present invention is not limited to these and, for example, with reference to Figure 3B, the extension of the direction of the opening structure 1400 can pass outside the weaker seal 3700, for example, above it. In this case, the tear will also likely be through the films 1100 and 1200 above the weakest seal 3700, thereby avoiding cutting through the weakest seal 3700. An advantage of this approach is that it avoids the effort required to tear the weakest seal 3700.

[0076] In some embodiments, the opening structure 1400 comprises points, perforations and/or weakening holes made in the first film 1100 and/or in the second film 1200. In some embodiments, the holes can be made through all of the films 1100 and/or 1200. This is particularly the case for the stronger seal 1300, as this facilitates cutting thereof. With regard to weaker sealing, holes can either be made all over the films 1100 and/or 1200, or only through some of their thickness or part of their layer(s). In the latter case, holes can be drilled at least through the oriented outer layers.

[0077] In some embodiments, the opening structure 1400 is configured to facilitate cutting of the first film 1100 and/or the second film 1200 so as to leave at least part of the weaker seal exposed to the environment. For example, with reference to Figure 2D it can be seen how the seal 2700 remains at least partially exposed to the outside, or the environment, once the aperture structure 1400 has been operated. In this manner, once the weaker seal 2700 is subsequently opened and pressure is applied to the cavity 1500, it may be possible to accurately control the leakage of fluid 1600 from the cavity 1500 once the weaker seal 2700 is opened. in direct contact with the environment and its position is easily visible to the user.

[0078] Although in the embodiments described above, the bag 2000, 3000, 4000 is generally illustrated as a rectangle, it should be understood that the invention is not limited to it and the bag can have non-rectangular shapes, such as, for example, the way illustrated in Figure 6 by bag 6000.

[0079] Furthermore, although in the above embodiments the tighter seal 1300 is generally illustrated as completely encircling the cavity and the weaker seal, the present invention is not limited thereto. In some embodiments, as illustrated, for example, in Figure 6 by pouch 7000, opening structure 7140 can be made in the shape of a lid. In this embodiment, the aperture structure 7140 can be seen as part of the stronger seal 7300 with the cooperation of the structure 7140 with the stronger seal 7300 and the weaker seal 7700 ensuring that no fluid can escape from the cavity 1500. the aperture, or lid, structure 7140 is opened, the weaker seal 7700 may operate as in the previously described embodiments. The advantage of this approach is that it combines the previously described advantage of being able to precisely control the timing at which fluid is poured from the bag 7000, along with the ability to close the bag 7000 for later use if needed.

[0080] Additionally, although in the above-described embodiments the weakest seal has been illustrated as being placed approximately in the middle of the pouch and having a lateral X dimension smaller than the lateral X dimension of the pouch, the present invention is not limited thereto.

[0081] For example, as illustrated in Figure 8, the weaker seal 2700 could also be placed closer to one side of the pouch 8000 rather than to the middle thereof. In another example, as illustrated in Figure 9, the weaker seal 9700 may have a side size comparable to that of the pouch 9000. Although this results in more difficulty in determining the precise location at which fluid will leak out of the pouch, it facilitates the opening of the bag 9000. There may be cases, for example, when the fluid 1600 is a washing machine detergent, where it is desirable for the fluid 1600 to exit the bag with a slight pressure, such as that applied by clothes during washing. washing machine operation, and the specific opening point of the weakest seal 9700 is not relevant.

[0082] Alternatively, or in addition, as illustrated in Figure 10, the weakest seal 10700 may comprise at least one widest part 10702 and at least one narrowest part 10701 such that upon delamination of the weakest seal 10700, the opening will start from the narrowest part 10701.

[0083] It should further be understood that a similar effect can be obtained by providing a weaker sealing force on part 10701 of the weaker seal 10700 and a stronger sealing force on another part 10702 of the weaker seal 10700. In this case , the part 10701 with the weakest sealing strength would also be opened before the part 10702 with the strongest sealing strength, thereby facilitating spillage of the liquid.

[0084] While some of the preferred embodiments of the present invention have been described or specifically exemplified above, it is not intended that the invention be limited to such embodiments. Rather, it should be understood that, although numerous features and advantages of the present invention have been set forth in the above description, along with details of the structure and function of the invention, the description is illustrative only, and changes may be made in the details, especially in matters of shape, size and arrangement of parts, within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. List of reference numbers

Claims (8)

1. Fluid bag, comprising: - a first skin (1100) and a second skin (1200) connected to each other by means of a stronger seal (1300, 5301-5303, 6300, 7300, 8300, 9300) and a weaker seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) to form a cavity (1500) for a fluid, and an opening structure (1400) configured to facilitate opening the first film (1100) and/or the second film (1200) along at least a first length; wherein the cavity (1500) has a perimeter and said perimeter comprises at least a part of the stronger seal (1300, 5301-5303, 6300, 7300, 8300, 9300) and at least a part of the weaker seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700); - the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) being close to the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300); - the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) and the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300) are configured so that the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) opens only if at least a first portion of the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300) is opened or removed; the pouch being characterized by the fact that: - the first length passes through at least a first portion of the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300); and - the first length still goes through at least a part of the weaker seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700). 2. Bag, according to claim 1, characterized in that the first length crosses only parts of the first skin (1100) and/or the second skin (1200) in which the strongest sealing (1300, 5301-5303, 6300 , 7300, 8300, 9300) or weaker seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) are present. 3. Pouch according to any one of claims 1 or 2, characterized in that the opening structure (1400) comprises weakening points and/or holes made in the first skin (1100) and/or in the second skin (1200) . 4. Bag according to any one of claims 1 to 3, characterized in that the opening structure (1400) is configured to facilitate the cutting of the first film (1100) and/or the second film (1200) in order to leave at least a portion of the weaker seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) exposed to the environment. 5. Bag, according to any one of claims 1 to 4, characterized in that the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) has a length (2701) equal to or less than 50 mm, preferably equal to or less than 30 mm, even more preferably equal to or less than 10 mm and/or a width (2702) equal to or less than 5 mm, preferably equal to or less than 3 mm, even more preferably, equal to or less than 1 mm. 6. Bag according to any one of claims 1 to 5, characterized in that the first skin (1100) and/or the second skin (1200) comprises a mixture of ionomer and polypropylene. 7. Bag, according to any one of claims 1 to 6, characterized in that the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300) has a sealing strength above 15N/15 mm, preferably above 40N/15 mm, and/or where the weaker seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) has a seal strength of 1-8N/15 mm, preferably 2-3N/15 mm. 8. Method for manufacturing a fluid bag, the method comprising the steps of: - providing a first film (1100) and a second film (1200), - connecting the first film (1100) and the second film (1200) one by one another in order to form a cavity (1500) for the fluid by performing a stronger seal (1300, 5301-5303, 6300, 7300, 8300, 9300), a weaker seal (2700, 3700, 4700, 5701- 5703, 7700, 9700, 10700, 11700), and an opening structure (1400) configured to facilitate opening the first film (1100) and/or the second film (1200) along at least a first length; the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) being made in the vicinity of the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300); - the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) and the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300) are configured so that the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700) open only if at least a first portion of the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300) is opened or removed; the method being characterized by the fact that: - the first length passes through at least a first portion of the strongest seal (1300, 5301-5303, 6300, 7300, 8300, 9300); and - the first length still goes through at least a part of the weakest seal (2700, 3700, 4700, 5701-5703, 7700, 9700, 10700, 11700).

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