Abstract:
A container for mixing an enclosed medical agent with a fluid. The container comprising an inclining bottom seam directed towards a connector. The connector comprising an elongated hollow body having a plurality of interconnected walls defining a first and a second longitudinal flow channel for fluidly connecting an inside and an outside of the container. The first flow channel has a first opening and a second opening, the first opening of the first flow channel is devised to be arranged inside of the container and the second opening of the first flow channel is devised to be arranged outside the container. The first opening of the first flow channel is arranged radially outwards from the first flow channel and directed towards said inclined bottom seam. The second flow channel has a first opening devised to be arranged inside of said container and a second opening devised to be arranged outside the container arranged axially to the first opening of the second flow channel.

Description:
RELATED APPLICATIONS 
     This application is the U.S. National Phase under 35 U.S.C. §371 of International Patent Application No. PCT/EP/2012/062275, filed on Jun. 25, 2012, and published in English on Dec. 27, 2012 as WO 2012/175753, which claims priority to European Application No. 11171247.7, filed Jun. 23, 2011. The contents of these applications are expressly incorporated herein by reference in their entireties. 
     BACKGROUND OF THE INVENTION 
     Field of the Invention 
     This invention pertains in general to the field of providing solutions, particularly medical solutions. More particularly the invention relates to a multi compartment container and a connector, as well as a method, for providing a medical solution, such as a dialysate solution. 
     Description of the Related Art 
     EP2035059 discloses a container comprising a plurality of compartments separated by compartment dividers, and an inlet connector for receiving a liquid via a connection tube. The compartment dividers rupture when a sufficient pressure is applied by a liquid or gas introduced into the container through the inlet connector. Some of the compartments comprise powder, which dissolves at the introduction of liquid into the container. 
     The disclosed container has vertically positioned compartment dividers which is not always an optimal arrangement for providing a thoroughly mixing of a solution. Further, the connection to the mixing system is made by either separated inlets or outlets or by alternating a flow through an inlet being a tube by a valve or a pump. The document also discloses a double lumen connector being two cannulas. But there is no teaching of how to configure the combined inlet/outlet and how to arrange the inlet/outlet in relation to the features of the container to obtain an optimized mixing and/or improve control of the opening of the peelable dividers. 
     Thus, there is a need for an improved solution to the container and connector combination to obtain a better mixing of a solution inside the container. It is also desired to improve the precision and quality of the final medical solution for providing to a patient. The improvement should also provide for time savings by decreasing the dissolving time and thus the effectiveness of the mixing. The invention may also be seen as an alternative to what is hitherto available, preferably more cost-effective. 
     Hence, an improved combination of a container and connector would be advantageous and in particular for improving the quality of a medical solution and allowing for increased flexibility and effectiveness would be advantageous. 
     SUMMARY OF THE INVENTION 
     Accordingly, embodiments of the present invention preferably seek to mitigate, alleviate or eliminate one or more deficiencies, disadvantages or issues in the art, such as the above-identified, singly or in any combination by providing devices and methods according to the appended patent claims. 
     According to a first aspect, a container is provided for mixing an enclosed medical agent with a fluid. The container has an inclining bottom seam directed towards a connector. The connector includes an elongated hollow body having a plurality of interconnected walls defining a first and a second longitudinal flow channel for fluidly connecting an inside and an outside of the container. The first flow channel has a first opening and a second opening, the first opening of the first flow channel is devised to be arranged inside of the container and the second opening of the first flow channel is devised to be arranged outside the container. The first opening of first flow channel is arranged radially outwards from the first flow channel and directed towards the inclined bottom seam. The second flow channel has a first opening devised to be arranged inside of the container and a second opening devised to be arranged outside the container arranged axially to the first opening of the second flow channel. 
     According to an aspect of the disclosure, a fluid connector device is provided for a container. The connector comprises an elongated hollow body having a plurality of interconnected walls defining a first and a second longitudinal flow channel fluidly connecting an inside and an outside of the container. The first flow channel has a first opening and a second opening, the first opening of the first flow channel is devised to be arranged inside of the container and the second opening of the first flow channel is devised to be arranged outside the container. The first opening of first flow channel is arranged radially outwards from the first flow channel. The second flow channel has a first opening devised to be arranged inside of the container and a second opening devised to be arranged outside the container arranged axially to the first opening of the second flow channel. The body comprises a tapered protruding member, a fastening section for fastening the connector device to the container, and a directing section positioned adjacent to the first opening of the first flow channel for directing a flow of a fluid through the first opening of the first flow channel. 
     In some embodiments, the first opening of the first flow channel is circumferentially positioned around an outer surface of a wall of the first flow channel. 
     In some embodiments, the first flow channel has an axially decreasing flow cross-section towards the first opening, and/or wherein a first wall surrounding the second flow channel is conically tapering towards the outside of the container and the first wall is an interior wall of the first flow channel and a second wall is surrounding the first flow channel without tapering to provide the axially decreasing flow cross-section. 
     In some embodiments the fastening section is adapted to be attachable to a bottom seam of the container. 
     In some embodiments, the directing section is further including a distancing unit for keeping a wall of the container at a distance from the first opening of the first flow channel. In this manner, unintended fluid stop is prevented. 
     In some embodiments, the connector is operable in different operation modes, including a first operation mode, wherein the first channel and the second channel inlet channels; a second operation mode, wherein the first channel is an inlet and the second channel is an outlet; and/or a third operation mode, wherein the first channel and the second channel are outlets. 
     In some embodiments, the second elongate body is arranged longitudinally inside the first elongate body and having a first end and a second end. 
     In some embodiments, first ends of the first and second elongate bodies are axially offset, and/or wherein the second elongate body is arranged coaxially inside the first elongate body, and/or wherein the second fluid channel is a central through channel. 
     In some embodiments, the fluid connector device is a combined inlet and outlet connector, and/or the first and second bodies are integrally in a single monolithic unit. This provides for advantageously cheap manufacture of the device. 
     In some embodiments, the first opening of the second flow channel is axially offset towards the interior from the first opening of the first flow channel. In this manner, the length of the protruding end into the container can be adjusted for optimal mixing. 
     In some embodiments, an internal axial recess is arranged at the first flow channel&#39;s first opening. This provides for an improved mixing thanks to a more turbulent flow. 
     In some embodiments, the directing means is arranged for providing a substantially lateral flow entering the container when the first flow channel is an inlet. The second flow channel may be an inlet or an outlet at the same time in different operation modes. This provides for an advantageous flow pattern for mixing. 
     According to another aspect of the disclosure, a container for providing a medical solution to be mixed in the container is provided. The container comprises preferably a fluid connector device according to the first aspect of the invention. The container has at least two substantially longitudinally positioned and peelable compartment dividers arranged to releasably separate at least three longitudinal compartments of the container. A plurality of compartments is subdivided by the compartment dividers, wherein at least a first compartment of the three longitudinal compartments contains a powder substance to be mixed with a liquid to provide the medical solution. At least a fourth compartment adjacent the three longitudinal compartments are empty from a substance prior to mixing the medical solution. The fluid connector device is arranged at a bottom of the container for connection of the container to a liquid providing system. The fluid connector is in fluid communication with the second compartment only prior to a mixing operation for providing the medical solution, and wherein the connector is arranged to come into fluid communication with the three longitudinal compartments upon supplying a liquid pressure through the fluid connector for simultaneously opening the compartment dividers. In this manner, a quick and reliable high quality mixing is provided. No separate mixing container is needed. Dissolving of powder substances I provided very effectively without risk for residual particles. 
     In some embodiments, the container is a flexible bag. The container may has beveled and/or rounded lower edges. The fluid connector is advantageously arranged at a bottom seam of the container (in operation of the container). The flexible bag&#39;s walls may be made of a laminate having an outer layer of Polyethylene terephthalate (PET) polymer and an inner layer of polyethene. There is no polyamide reinforcement layer. 
     In some embodiments, the empty compartment is obtained by a substantially vertically positioned compartment divider and parts of two longitudinally compartment dividers. 
     In some embodiments, the empty compartment is obtained singly by a curved, i.e. not straight, compartment divider or by the curved compartment divider in combination with parts of two longitudinally compartment dividers. 
     In some embodiments, the compartment dividers of the empty compartment are arranged to open completely when enough pressure of a fluid is applied. 
     In some embodiments, the compartment dividers are adapted to open either simultaneously and/or subsequently in a defined sequence. 
     In some embodiments, the compartment dividers are fully open when a mixing action starts. 
     In some embodiments, the container is made of two layers of material and wherein the compartment dividers are welded by applying a level of heat and the strength of the compartment dividers are controlled by the level of applied heat. The flexible bag&#39;s walls may in particular for this purpose be made of a laminate having an outer layer of Polyethylene terephthalate (PET) polymer and an inner layer of polyethene. 
     In some embodiments, at least two compartments of the at least four comprises a powder and at least one of the three compartments comprises a solution. 
     According to a further aspect of the disclosure, a combination of a connector of the first aspect of the invention, and a container of the second aspect of the invention is provided. The connector is fastened to the bottom seam of the container by the fastening section of the tapered protruding member, and wherein the fluid direction section are arranged to direct a flow of a fluid towards the beveled and/or rounded lower edges and thereby create a circulatory circulation in the container. 
     According to another aspect of the disclosure, a method is provided for obtaining a medical solution using a combination of the third aspect of the invention. The method comprises several operation modes for this purpose. In a first operation mode a flow of a fluid is introduced into the container through a first and second channel of the connector communicating with a fluid source. Compartment dividers are opened of an empty compartment and subsequently the longitudinal compartment dividers by a pressure created by a volume of fluid introduced into the container through the connector caused by the flow. A turbulent circulatory circulation is obtained in the container by directing the flow of the fluid towards the beveled and/or rounded lower edges using the direction section. The introduction of the fluid is stopped when a predetermined volume is introduced into the container. A second operation mode comprises mixing a content of the container including the introduced fluid by re-circulation of the content for obtaining the medical solution, including simultaneously using the connector as an combined inlet and outlet for the re-circulation by the first channel operating as an inlet and the second channel as an outlet, whereby a second turbulent circulatory circulation is obtained in the container for the mixing. 
     In yet a further aspect of the disclosure, a method is provided for obtaining a medical solution. The method comprises preferably using a container according to any of the above aspects. The method comprises a first operation mode comprising introducing a flow of a fluid into the container through a first and/or second channel of the connector communicating with a fluid source; opening compartment dividers of an empty compartment and subsequently compartment dividers by a pressure created by a volume of fluid introduced into the container through the connector, obtaining a turbulent circulatory circulation in the container by directing the flow of the fluid towards an inclined bottom seam and/or beveled edges of the container, stopping the introduction of the fluid when a predetermined volume is introduced into the container. In a second operation mode the method comprises mixing a content of the container including the introduced fluid by re-circulation of the content for obtaining the medical solution, including simultaneously using the connector as an combined inlet and outlet for the re-circulation by the first channel operating as an inlet radially directing the fluid towards the inclined bottom seam and/or beveled edges, and the second channel as an outlet, whereby a second turbulent circulatory circulation is obtained in the container for the mixing. 
     In some embodiments, the second turbulent circulatory circulation is a flow circulation pattern comprising a turbulent flow flowing radially outward from the first channel of the connector, up along an outer edge towards a top section of the container, turning inwardly towards a central section of the container and flowing back down to the connector for leaving the container towards a re-circulation pump via the second channel of the connector, and from the re-circulation pump back to the first channel of the connector for continued internal circulation in the container. 
     Thus an effective mixing is achieved. 
     The mixing system comprising the pump may be of the type disclosed in EP2035059, which is incorporated herein by reference in its entirety. 
     According to a fifth aspect of the invention, a method is provided. The method is a method for emptying a provided medical solution obtained according to the fourth aspect of the invention, a combination according to the third aspect of the invention. The method comprises stopping the re-circulating action; and emptying the medical solution from the container through the connector in a third operation mode, wherein the first channel and the second channel of the connector are outlets. 
     A large flow for emptying the container is thus possible. The container may be completely emptied leaving minimum residues in the container for recycling or disposal. This is environmentally advantageous. 
     Further embodiments of the invention are defined in the dependent claims, wherein features for the second and subsequent aspects of the invention are as for the first aspect mutatis mutandis. 
     It should be emphasized that the term “comprises/comprising” when used in this specification is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps, components or groups thereof. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       These and other aspects, features and advantages of which embodiments of the invention are capable of will be apparent and elucidated from the following description of embodiments of the present invention, reference being made to the accompanying drawings, in which 
         FIG. 1A-D  is showing schematic cross-sections of an exemplary embodiment of a connector; 
         FIG. 1E-F  is showing schematic  3 D views of an exemplary embodiment of a connector; 
         FIG. 1G  is showing a schematic cross-section view of an exemplary embodiment of the connector when used as a combined inlet and outlet; 
         FIG. 2A-C  is showing schematic cross-sections of an exemplary embodiment of a connector; 
         FIG. 2D-E  is showing schematic  3 D views of an exemplary embodiment of a connector; 
         FIG. 2F  is showing a schematic cross-section view of an exemplary embodiment of the connector when used as a combined inlet and outlet; 
         FIG. 3A  is showing a schematic illustration of an exemplary embodiment of a container with a connector; 
         FIG. 3B  is showing a schematic illustration of another exemplary embodiment of a container with a connector; 
         FIG. 3C  is showing a schematic illustration of a further exemplary embodiment of a container with a connector; 
         FIG. 4A  is showing a schematic cross-section of an exemplary embodiment of a connector fastened to a container when both flow channels are used as inlets; 
         FIG. 4B  is showing a schematic cross-section of an exemplary embodiment of a connector fastened to a container and one flow-channel is used as an inlet and another as an outlet, simultaneously; and 
         FIG. 4C  is showing a schematic cross-section of an exemplary embodiment of a connector fastened to a container when both flow channels are used as outlets and the compartment dividers are ruptured. 
     
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Specific embodiments of the invention will now be described with reference to the accompanying drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. 
     The following description focuses on embodiments of the present invention applicable to be used with a dialysis system and in particular to the preparation of a dialysis liquid or dialysate concentrates of different concentrations using powder concentrates. However, it will be appreciated that the invention is not limited to this application but may be applied to many other examples of systems were it may be an advantage to provide powders to be mixed with a liquid to be used with, for example, a solution providing system. Thus, medical solutions prepared by the exemplary embodiments described below may be used in dialysis treatments, as concentrate solutions or ready-made solutions for dialysis, as infusion solutions, such as Ringer&#39;s lactate, as nutrition solutions, as replacement solutions, as plasma expander solutions, etc. 
       FIG. 1A-G  is showing an exemplary embodiment of a connector  10 . The connector  10  is made of an elongated body  22  having interconnected walls to provide two flow channels, preferably being two elongated hollow bodies. 
     One of the hollow bodies is positioned axially arranged inside the other hollow body. 
     In the illustrated example, the cross section of both bodies is circular forming annular bodies. The bodies are in the illustrated example arranged co-axially. The bodies may in other examples have any shape of its cross-section, such as ellipsoid, or annular, or polygonal etc. 
     A proximal end (shown in the upper portion of  FIG. 1A ) of the connector  10  is arranged to be positioned inside a container and a distal end (shown in the lower portion of  FIG. 1A ) to be positioned outside of the container. At the distal end, the connector is provided with two openings  16 ,  17 . Preferably the openings  16 ,  17  are annular-shaped, but may additionally and/or alternatively be ellipsoid or polygonal. Additionally one of the bodies may be substantially centrally positioned, here the opening  16  of a first body, in relation to the opening  17  of the other body. In the illustrated example, the end edge of the first opening  16  of the inner body is axially recessed in relation to the end edge of the other opening  17  of the outer body. This may provide for a mechanical protection of the inner body, as well as a keying of the connection in order to provide a safety feature for preventing connection to non-compatible mixing systems. Additionally, there are two openings  11 ,  13  at the proximal end of the connector  10 . One of the openings  11  is positioned along a longitudinal axis of the connector  10  and the other opening  13  may be positioned radially outwards from the outer elongated body  22 . Preferably, the radially positioned opening  13  may surround the outer elongated body  22  circumferentially. 
     Further, the connector may comprise a protruding member  12  positioned between the distal end of the outer elongated body  22  and the opening  13  being positioned radially outwards from the outer elongated body  22 . Additionally and/or alternatively, the protruding member may extend from below radially outward opening  13  to above the opening  13 . 
     The protruding member  12  may have a fastening section  14  which may be positioned in the seam at the bottom of a container. The connector  10  may be fastened by welding through applying heat or by using glue or other suitable joining techniques to the container. Alternatively and/or additionally the fastening section  14  may have a shape being tapered from the outer elongated body  22 . Thus a smoother transit between the connector and the seam may be created. Alternatively and/or additionally, the tapered shape of the fastening section  14  may improve the sealing effect, the tightness, of the container material around the connector  10 . 
     Preferably the tapered part may have a wedge shaped or boat-shaped profile with straight walls. Alternatively, it may also be shaped slightly curved, e.g. elliptic, hull-shaped, or wing-shaped. 
     The upper part of the protruding member  12 , positioned above the radially outward opening  13 , and the top of the fastening section  14  may be a directing section  27  for directing a fluid in and out of the radially positioned opening  13 . The directing section  27  may, in some examples, have an H-shaped profile obtained between the outside of the top part of the fastening section  14  and the top part of protruding member  12 . The middle member  18  may improve the directing of the fluid. Alternatively and/or additionally the middle member  18  is positioned to increase the stability of the directing section  27 . 
     The H-shaped profile (see e.g.  FIG. 1D ) may provide a flow path, being the directing section  27 , between the top of the protruding member  12  and the fastening section  14 . This arrangement will improve the directing of the flow of a fluid from the radially positioned opening  13  when flowing into the container. Alternatively and/or additionally, the directing section may prevent the material of the container to obstruct the flow in and out of the radially positioned openings  13  of connector  10 . The obstruction could for instance occur when a compartment of the container surrounding the connector  10  is empty. This could occur at the initial stage when introducing a fluid into a container. Additionally and/or alternatively, the obstruction could occur when emptying the container and the container may get sucked into the opening  13  of the connector  10 . These kinds of obstructions are effectively prevented. 
     Further, the directing section may include distance units  20 , such as two struts, for improving the stability. Alternatively and/or additionally the struts  20  are positioned as spacers to avoid the container to obstruct the radially positioned opening  13 . 
     Additionally, in some examples, a build-up portion  19  may be positioned on-top of the protruding member  12 , sealing the outer body against the inner body. The build-up portion  19  is an inner protrusion in the body. When a flow of a fluid hits the inside of the build-up portion  19  the flow may have to go back to exit through the radially positioned opening. Thus a turbulent flow may be created which may increase the pressure of the flow out of the radially positioned opening  13 . This provides for advantageously improved mixing. 
     The distance between the top of the protruding member  12  and the axially positioned opening  11  in the container is decided by the dimensions of the container. Alternatively the distance may be adjusted to suit the dimension of a compartment of the container surrounding the connector  10 . 
     Additional and/or alternative feature in some embodiments of the connector  10  has a ridge  15  located around the outer surface of the elongated body  22  and located outside of the container. The ridge  15  may be used to increase the sealing effect between the connector  10  and a mixing system, for example by use of a mating O-ring. 
     As an additional and/or alternative feature in some examples of a connector  10 , a flat surface  21  may be located on the outside surface of the outer elongated body  22  and outside of the container. The flat surface  21  may be used to efficiently hold the connector  10  in position when attached to a mixing system, for example by engaging with a matingly provided fork-like tool. The connector may thus become efficiently locked to the mixing system. Rotational movement of the connector is prevented as well as longitudinal movement. This may be important when applying high pressure of fluids into the container through the connector  10 . 
     The connector  10  may be operated in at least three operational modes. 
     In one operational mode, both the opening  16 ,  17  of the elongated hollow bodies of the connector  10  are used as inlets to the container, to fast provide a volume of a fluid or a high pressure of a fluid into a container. 
     Additionally and/or alternatively, the flow from the radially positioned opening  13  and the flow from the axially positioned opening  11  will create a tubular motion inside the bag after the dividers have been opened. Hence the dissolvent and mixing will be improved inside the container. Further, this may increase the likelihood of complete rupture of the container&#39;s inner seams. 
     Additionally and/or alternatively the axially positioned opening  11  located inside the container may be closed at one point in time after the initial rupture of the compartment dividers. Hence the turbulent movement may change since it will only be maintained from to the radially flow out of the opening  13  of the connector  10 . This turbulent motion in the container may in some cases have an improvement on the mixing, for example it may decrease the likelihood of powder residuals along the inner sides of the container. 
     In another operation mode (see  FIG. 1G ), the inner flow channel  26  of the connector is used as an outlet and the outer flow-channel  25  as an inlet. Thus, by using an external pump, a re-circulation may be obtained in and out of the container which may improve the mixing of the content of the container since the re-circulation may be run continuously until sufficient mixing is obtained. During this operation further fluid may be added to the solution if needed but it is not necessary. If further fluid may be added or not depends on the configuration of the mixing system the container is connected to. Alternatively this operation mode may be run in the opposite direction using the inner flow channel  26  as an inlet and the outer flow-channel  25  as an outlet. 
     In a further operation mode, both flow-channels  25 ,  26  may be used as outlets to quickly empty the container. Using all openings  11 ,  13  inside the container as outlets may improve the efficiency of the emptying procedure. The time for emptying the container may thus be decreased. Additionally the amount of solution left in the container when emptied and the container is discharged may be minimized. The speed is improved by using both flow channels as outlets and the amount of solution left in the container is minimized by the opening  13  being radially positioned and preferably located at the lowest point at bottom of the container. Hence, an increased draining of solution from the container may be provided in a cost and time efficient manner. 
     Alternatively and/or additionally, in some examples of the connector  10 , the flow cross-sectional area of the outer flow-channel will slightly decrease from opening  17  to opening  13 , such as V-shaped. This can be seen in  FIG. 1A . By decreasing the flow cross-sectional area of the flow channel the pressure may increase of the flow out of the radially positioned opening  13 . 
       FIG. 2A-F  is showing an exemplary embodiment of a connector  110 . The connector  110  is made of an elongated body  122  having interconnected walls to provide two flow channels, preferably being two elongated hollow bodies. 
     One of the hollow bodies is positioned axially arranged inside the other hollow body. 
     The bodies may have any shape of its cross-section, such as ellipsoid, or annular, or polygonal etc. 
     A proximal end of the connector is arranged to be positioned inside a container and a distal end to be positioned outside of the container. At the distal end, the connector is provided with two openings  116 ,  117 . Preferably the openings are annular-shaped, but may additionally and/or alternatively be ellipsoid or polygonal. Additionally one of the bodies may be substantially centrally positioned  116  in relation to the other  117 . Additionally, there are at least two openings  111 ,  113  at the proximal end of the connector  110 . One of the openings  111  is positioned along an axis of the connector  110  and the other opening  113  may be a radial tube positioned radially outwards from the outer elongated body  22  and in fluid communication with one of the flow channels. The edge of the inner opening may be longitudinally recessed in relation to the edge of the outer opening. Preferably the radially positioned opening  113  may be two radial tubes directed in opposite directions from the outer elongated body  122 . 
     Further the connector may comprise a protruding member being a fastening section  114 , positioned between the distal end of the outer elongated body  122  and the radial tube  113 . The fastening section  114  may be positioned radially outwards from the outer elongated body  122 . 
     The fastening section  114  may be positioned in the seam at the bottom of a container for fastening the connector  110  to a container. The connector  110  may be fastened by welding through applying heat or by using glue or other suitable joining techniques. Alternatively and/or additionally the fastening section  114  may have a shape being tapered from the outer elongated body  122 . Thus a smoother transit between the connector and the seam may be created. Alternatively and/or additionally, the tapered shape of the fastening section  114  may improve the sealing effect, the tightness, of the container material around the connector  110 . 
     Preferably the tapered part may have a wedge shaped or boat-shaped profile with straight walls. Alternatively, it may also be shaped slightly curved, e.g. elliptic, hull-shaped, or wing-shaped. 
     The radial tube of the opening  113  is arranged to improve the directing of the flow of a fluid from one of the fluid channels. Alternatively and/or additionally, the radial tube of the opening  113  may prevent the material of the container to obstruct the flow in and out of the radially positioned openings  113  of connector  110 . The obstruction could occur when a compartment of the container surrounding the connector  110  is empty. This could occur at the initial stage when introducing a fluid into a container. Additionally and/or alternatively, the obstruction could occur when emptying the container and the container may get sucked into the opening  113  of the connector  110 . 
     Additionally, in some examples, a build-up portion  119  may be positioned on-top of the outer elongated body  122 , sealing the outer body against the inner body. The build-up portion  119  is an inner protrusion in the body. When a flow of a fluid hits the inside of the build-up portion  119  the flow may have to go back to exit through the radially positioned opening. Thus a turbulent flow may be created which may increase the pressure of the flow out of the radially positioned opening  113 . 
     The distance between the radial tube of opening  113  and the axially positioned opening  111  inside the container is decided by the dimensions of the container. Alternatively the distance may be adjusted to suit the dimension of a compartment of the container surrounding the connector  110 . 
     Additional and/or alternative feature in some embodiments of the connector  110  has a ridge  115  located around the outer surface of the elongated body  122  and located outside of the container. The ridge  115  may be used to increase the sealing effect between the connector  110  and a mixing system, for example by use of an O-ring. 
     Additional and/or alternative feature in some examples of a connector, a flat surface  121  may be located on the outside surface of the outer elongated body  122  and outside of the container. The flat surface  121  may be used to hold the connector  110  in position when attached to a mixing system, for example by engaging with a matingly provided fork-like tool. The connector may thus become efficiently locked to the mixing system. Rotational movement of the connector is prevented as well as longitudinal movement. This may be important when applying high pressure of fluids into the container through the connector  110 . 
     Similar to the connector of  FIG. 1A-G , this connector  110  may be operated in at least three operational modes. As an example, 
       FIG. 2F  shows the flow through the connector during re-circulation mode were the inner flow channel  126  of the connector is used as an outlet and the outer flow-channel  125  is used as an inlet. 
       FIG. 3A-C  shows three examples of containers  30 ,  40 ,  50  such as a bag, with the connector  200 . In  FIG. 3A-B  the longitudinally positioned compartment dividers  34 ,  44  are separating the three compartments A, B, C. The compartment dividers may have any shape such as substantially straight, v-shaped or zigzag. 
     Longitudinally positioned compartment dividers  34 ,  44  may improve the opening or rupture of the compartment dividers  34 ,  44  since the opening may be smoother. Additionally the compartment dividers will be closer to the initial opening which will reduce the risk of the compartment dividers  34 ,  44  not opening at fully adjacent to the walls  31 ,  41 . If not fully opened, there may be an increased risk of powder deposition (i.e. residuals) or aggregations at the locations of where the compartment divides  34 ,  44  meets the walls  31 ,  41 . This may improve the mixing and the precision of the concentration. Further the concentration may be more even throughout of the container  30 ,  40  due to the further improved circulation since the interior of the walls  31 ,  41  may be more even. 
     Additionally and/or alternatively, the mixing will be improved since longitudinally positioned compartment dividers  34 ,  44  avoids unopened parts of the compartment dividers adjacent to the interior side of the longitudinal part of the outer walls  31 ,  41 . 
     Additionally, the container  30 ,  40  may further comprise an empty compartment D surrounding the connector  200 . This could be obtained by a substantially vertically positioned compartment divider  35  ending adjacent to the longitudinally positioned compartment dividers  34 , as in  FIG. 3A . 
     Additionally and/or alternatively, in some embodiments the empty compartment D surrounding the connector  200  could be made by a curved compartment divider  45  which either adjacent the longitudinally positioned compartment dividers  45  or adjacent the bottom surface, as in  FIG. 3B . 
     This empty compartment may improve the opening of the longitudinally positioned compartment dividers by providing an initiate even pressure on bottom part of the longitudinally positioned compartment dividers  34 ,  44  when filled with a fluid by the connector  200 . 
     In  FIG. 3C  a container  50  is showed having vertically positioned compartment dividers  54 . The compartment dividers may have a V-shaped portion  56 . The V-shaped portion  56  may improve the opening and/or rupture of the compartment dividers  54 . The V-shaped portion  56  may be used to control the opening of the compartment dividers  54 . The opening and/or rupture will begin at the tip of the V-shaped portion  56 , thus the opening and/or rupture may be smooth and controlled and not explode. Additionally the opening and/or rupture of the compartment dividers will be quiet. If no V-shape portion  56  the compartment dividers  54  may open with a bang. 
     The V-shaped portion  56  may be positioned anywhere along the compartment dividers  54 . By positioning the V-shaped portion closer to the wall were the container is being filled, weakening of the seam and/or unintentional opening and/or rupture may be prevented. 
     Additionally, similar to the containers in  FIG. 3A-B  the container in  FIG. 3C  may comprise a further compartment D being empty. The compartment D may surround the connector  200  by compartment divider  55 . Also one of the sides of the compartment D and the compartment divider  55  may have a V-Shaped part  57  to better control the opening and/or rupture. 
     In  FIG. 3A-C , at least one of the compartments contains a powder and the other compartments may contain either powders or liquids. The powders and liquids are provided in suitable amounts for providing a defined solution when mixed with a predetermined amount of fluid from an external supply source. The solution is provided by dissolving the powder in a fluid, such as water, and by mixing the water with the content of the compartments. The fluid is applied through the connector from an external supply source. 
     The compartment dividers  34 ,  44 ,  54  differ from the seam or weld  31 ,  41 ,  51  by opening and/or rupture when a pressure of a fluid is applied through the connector  200 . The opening and/or rupture of the compartment dividers may be due to directly applied pressure from the flowing fluid. Alternatively and/or additionally the opening or rupture of the compartment dividers may be due to an expansion of a compartment due to an increase in volume of the compartment when a fluid is applied through the connector  200 . 
     The compartment dividers  34 ,  44 ,  54  may be controllable opened and/or ruptured by controlling the flow of the fluid through the connector  200 . 
     Additionally and/or alternatively, in some examples the dividers  34 ,  44 ,  54  are sequentially opened and/or ruptured. Alternatively all compartments dividers  34 ,  44 ,  54  may opened simultaneously. 
     Additionally and/or alternatively, by varying the strength of the compartment divides  34 ,  44 ,  54  for example by increasing the applied heat when welding, the compartment dividers  34 ,  44 ,  54  may be opened subsequently. 
     Additionally, the sizes of the compartments may decide by the amount of powder or liquid content of each compartment needed to obtain the final solution. 
     The bottom surface  32 ,  42 ,  52  of the container  30 ,  40 ,  50  may be inclined and has beveled and/or rounded lower edges  33 ,  43 ,  53 . This may direct the content of the container  30 ,  40 ,  50  towards the lower point of the container while the rounded edges  33 ,  43 ,  53  may reduce the risk that contents of the container  30 ,  40 ,  50  may remain at the walls  31 ,  41 ,  51  and in the interior edges of the container  30 ,  40 ,  50 . This may improve the mixing of the solution. 
     Additionally and/or alternatively, the inclined bottom  33 ,  43 ,  53  in combination with the beveled and/or rounded edges  33 ,  43 ,  53  may increase the circulation and improve the mixing action in the container  30 ,  40 ,  50 , which may improve the mixing of the solution. 
     Additionally and/or alternatively, the combination of the above described construction of a container  30 ,  40 ,  50  with a connector  200  having at least one radially positioned opening directed towards the inclined bottom  33 ,  43 ,  53  and beveled edges  33 ,  43 ,  53  may further improve the circulation of the fluid during opening of the divides  34 ,  44 ,  54 , Also, the combination may improve recirculation of the solution, thus improving the mixing of the solution. 
     Additionally and/or alternatively, the inclined bottom surface  31 ,  41 ,  51  of the container  30 ,  40 ,  50  may positioning the connector  200  with its radially positioned opening closely at the lowest point of the container  30 ,  40 ,  50  and adjacent to the junction of the two inclined surfaces of the container. This increases the efficiency of emptying the container since the solution may flow towards the lower positioned openings. 
       FIGS. 4A-C  is showing a combination of a container  30 ,  40 ,  50  and a connector  200 . The figures show examples of different fluid flows and operation modes during different stages of the mixing. The connector  200  may be a connector according to the examples given hereinbefore. 
     A controlled circling flow pattern improves the mixing in the container. For example, the risk of residuals left along the sides and in the corners of the container may be reduced and the dissolvent of the powders with the applied fluids may increase. Examples of fluid flows are shown in  FIGS. 4A-C , showing recirculation and/or circular flow patterns. 
     In more detail,  FIGS. 4A-C  are illustrating different mixing modes and stages of the mixing action of the container. The container  60 ,  70 ,  80  in combination with a connector  200  may be operated in at least three modes. 
     In one operation mode, see  FIG. 4A , both the opening of the elongated hollow bodies of the connector  200  are used as inlets to the container  60 ,  70 ,  80  to fast provide a volume of a fluid or a high pressure into the container  60 ,  70 ,  80 . This may improve the likelihood of complete opening of the peelable compartment dividers. By applying the fluid radially towards the inclined bottom  62 ,  72 ,  82  and beveled edges  63 ,  73 ,  83  a pressure will be applied along inside of the longitudinal outer welds thus, the likelihood of a fully peeled compartment divider adjutant the interior walls of the container increases. 
     Additionally and/or alternatively, the flow from the radially positioned opening and the flow from the axially positioned opening will create a tubular circulation inside the container  60 ,  70 ,  80 . Hence the dissolvent and mixing will be improved inside the container  60 ,  70 ,  80 . 
     Additionally and/or alternatively the axially positioned opening of the connector  200 , located inside the container  60 ,  70 ,  80 , may be closed at one point in time after the initial rupture of the compartment dividers. Hence the circular circulation will change since it will only be maintained from to the radially flow out of radially positioned openings of the connector  200 . The radial flow will be directed towards the inclined bottom and beveled edges, thus the circulation pattern will change which may in some cases have an improved effect on the mixing 
     After breaking the empty compartment D mixing with the contents in the first compartment, which comprises a powder, is initiated. A first turbulent circulatory circulation is provided with a high flow rate of fluid through the connector  200  to fill the first compartment with a desired volume. This turbulent circulation may be vicious. Filling the container under high pressure may help to quickly peel the dividers. Further, by filling the compartment fast under turbulent circulation, lumps and/or aggregations of powder particles may be prevented. 
     In a second operation mode (see  FIG. 4B ), the axially directed opening of the connector  200  may be used as an outlet and the radially directed flow-channel as an inlet. Thus a re-circulation is obtained in and out of the container  60 ,  70 ,  80  which will improve the mixing of the content in the container. 
     The turbulent circulatory circulation of the recirculation mode is provided as a flow circulation pattern comprising a turbulent flow flowing radially outward from the first channel of the connector, up along an outer edge towards a top section of the container, turning inwardly towards a central section of the container and flowing back down to the connector for leaving the container towards a re-circulation pump via the second channel of the connector, and from the re-circulation pump back to the first channel of the connector for continued internal circulation in the container. 
     As the bottom surface  62 ,  72 ,  82  of the container  60 ,  70 ,  80  is inclined and has beveled and/or rounded lower edges  63 ,  73 ,  83 , the mixing flow in the container is very efficient. This improved mixing action is further improved by combining the described container with the connector  200  which will improve the circulation in the container. Further the archived circulation in the container may reduce the risk that contents, such as powder residuals and/or lumps, remain at the interior walls or interior edges. 
     Additionally and/or alternatively, this mode may be run before peeling the next divider. 
     Additionally and/or alternatively, this mode may be run in the opposite direction, using the axially directed opening of the connector  200  as an inlet and the radially directed flow-channel as an outlet. 
     In a third operation mode, see  FIG. 4C , both flow-channels will be used as outlets to empty the container  60 ,  70 ,  80 . A high out flow may thus be provided without the need of additional outlets. The use of two openings of the connector  200  inside the container as outlets may improve the efficiency of the emptying procedure. The time for emptying the container could be decreased. Further the amount of residual solution left in the container when emptied and the container is discharged may be minimized. 
     The speed of the emptying process is improved by using both flow channels as outlets and/or the amount of solution left in the container  60 ,  70 ,  80  is minimized by the openings being radially positioned. The preferred located are adjutant to bottom of the container. 
     The inclined bottom  62 ,  72 ,  82  of the container  60 ,  70 ,  80  positioning the connector  200  with its radially positioned opening close to the lowest point of the container and adjacent to the junction of the two inclined surfaces. This increases the efficiency of emptying the container since the solution may flow towards the lower positioned openings. Thus, the inclined bottom  62 ,  72 ,  82  directing the flow towards the radial openings of the connector  200 . 
     Hence, the mixing efficiency is significantly improved when using a connector according to the examples described here. The mixing efficiency is further improved by having and inclined bottom surface of the container to which the connector is connected. The compartment dividers are smoothly opened by a pressure created and causing peeling of the dividers. As the dividers open completely, they risk of leaving non dissolved residues is minimal. Thanks to the design of the container, there are no or little possibilities for residuals to be stuck to corners or to the compartment dividers. Thus the accuracy of the concentrations in the final solution may also be improved by the connector and container described herein. 
     Additionally, using a container with vertically positioned peelable dividers, any remaining residuals may fall down or be washed down to the connector outlet. 
     The container may be Z-folded to save space during transport or storage prior to the mixing action. When emptied, it may be folded again to save space for recycling or disposal. 
     The present invention has been described above with reference to specific embodiments. However, other embodiments than the above described are equally possible within the scope of the invention. Different method steps than those described above, performing the method by hardware or software, may be provided within the scope of the invention. The different features and steps of the invention may be combined in other combinations than those described. The scope of the invention is only limited by the appended patent claims.