DE102022128565A1 - Container with a connector with a membrane - Google Patents

Abstract

The invention relates to a container (40) for a dosing system (1) which can be positioned in the interior of a dishwasher and comprises a dosing device (10) through which at least one preparation can be dosed into the interior, wherein the container (40) has at least one chamber (41, 42, 43) for receiving the preparation and a connecting piece (44) assigned to the chamber (41, 42, 43), which is connected to the chamber (41, 42, 43) and can be connected to a connection receptacle (23) of the dosing device (10) to form a connection between the chamber (41, 42, 43) and the dosing device (10), and wherein the connecting piece (44) has a membrane (55) which is closed when new and is designed to be opened when the connecting piece (44) is connected to the connection receptacle (23). According to the invention, the connecting piece (44) has a base body (49) onto which the membrane (55) is integrally formed, wherein the base body (49) and the membrane (55) are made of the same material.

Description

The invention relates to a container for a dosing system which can be positioned in the interior of a dishwasher and comprises a dosing device through which at least one preparation can be dosed into the interior.

The EP 2 296 520 B1 discloses such a dosing system with a container and dosing device. A housing of the container forms several chambers, each of which stores a preparation. Each chamber is assigned a connector with which the container can be connected to the dosing device to form a liquid-tight connection. The dosing device has several connection receptacles for this purpose. The connector of the chamber can be connected to one of these connection receptacles. The dosing device and the container connected to it are then placed in the interior and a wash cycle can begin. The dosing device exchanges signals with the dishwasher so that the preparations can be dosed out of the chambers in a targeted manner at different times and in different quantities during the wash cycle, depending on various parameters.

The dosing device and container are detachably connected to each other, so that the container can be replaced when it is empty after several rinse cycles. EP 2 296 520 B1 is a plug-in connection between a connector and a connector receptacle, where the connector must be pressed into the connector receptacle with a certain amount of pressure to establish the plug-in connection. In particular, a membrane of the connector must be pierced, which, when the connector is new, protects the preparation in the chamber from environmental influences. The membrane is enclosed in a base body of the connector and is made of a soft material that is different from the material of the base body. When the connector is connected to the connector receptacle, the membrane is pierced by a mandrel or a hollow needle of the connector receptacle, whereby the force required to pierce the membrane is not great due to the soft material.

To produce the connector, a pre-manufactured membrane can be inserted into the base body of the connector. Subsequent assembly of the membrane is costly. It is also possible to inject the membrane onto the base body using multi-component injection molding, but this requires a complex multi-component injection molding machine. In addition, recycling the connector can be problematic if the material of the base body and the material of the membrane have to be separated from each other during recycling.

The invention is therefore based on the object of providing a container for a dosing system that can be placed in a dishwasher, which can be produced cost-effectively and in a resource-saving manner and whose replacement can be carried out easily.

The object underlying the invention is achieved with the combination of features according to claim 1. Embodiments of the invention can be found in the subclaims to claim 1.

According to the invention, the membrane is formed in one piece onto the base body of the connector, with the base body and membrane being made of the same material. This means that the connector can be manufactured as a one-piece injection-molded part made of plastic, whereby subsequent insertion of the membrane or subsequent injection molding of the membrane is not necessary. By using only one material, the connector or the entire container can also be recycled with less effort.

It must be ensured that piercing or tearing the membrane when connecting the connector and the connector receptacle does not require too much force. The membrane can therefore be very thin, for example between 0.01 and 0.5 mm or preferably between 0.04 and 0.2 mm. In one embodiment, the wall thickness of the membrane is 0.08 to 0.12 mm. Such a low wall thickness of the membrane can be achieved by subjecting the membrane to the force of a stamping tool after injection molding, which presses the wall thickness to the required level. Another way of producing a membrane with this low wall thickness is to provide a sprue opening in the immediate vicinity of the membrane in the injection mold.

The membrane can be made of polyolefin, preferably polypropylene. To ensure that the membrane tears reliably when the connector is connected to the connector holder without having to use too much force, the plastic from which the membrane and the base body are made can be filled with a filler. The brittleness of the plastic can be adjusted by choosing the filler and its content. Talc, silica, glass powder or glass beads, glass fibers, barium sulfate and kaolin can be used as fillers. A preferred filler is calcium carbonate (CaCO ₃ ). In one embodiment For example, in which polyolefin and preferably polypropylene (PP) is used as the plastic, the filler content is 1 to 10%, preferably 4 to 8%. The plastic for the base body and the membrane must not be too brittle so that it does not break under impact (which occurs, for example, if the container is accidentally dropped). The filler can also be a combination of different substances, for example a combination of calcium carbonate and talc.

In one embodiment, the grain size of the filler is selected such that a grain diameter of the filler is not greater than the wall thickness of the membrane. In the case of a non-round grain, the grain diameter should correspond to the largest extension or the largest diameter of the grain. The grain diameter is preferably smaller than half the wall thickness of the membrane.

In one embodiment, the base body has a welded part with an inflow channel, wherein the welded part is sealingly attached to a chamber wall of the chamber and the inflow channel is connected to the chamber. The base body can have a plug-in part with an outflow channel, wherein the plug-in part can be inserted into the connection receptacle. Insertion is preferably carried out by a linear movement. The plug-in part can then be pulled out of the connection receptacle again by an opposite linear movement.

The membrane can be arranged between the inflow channel and the outflow channel and can separate the inflow channel and the outflow channel when the container is new. If the membrane is punctured or torn, there is a connection between the inflow channel and the outflow channel so that the preparation can pass from the chamber to the connection receptacle of the dosing device. Before the membrane is punctured or torn, i.e. before the connection piece is connected to the connection receptacle, the membrane ensures that the chamber is airtight and liquid-tight. This protects the preparation in the chamber from environmental influences and allows it to be stored in the container for a longer period of time. The membrane only loses its sealing effect when the container is connected to the dosing device.

In one embodiment, the base body has an air chamber with an air chamber wall for ventilating the chamber, with a projection formed on the air chamber wall. The projection has a system for an abutment of the connection receptacle. The system is spaced apart from the air chamber wall so that a force that acts on the system of the projection when connecting the connection piece and connection receptacle creates a bending moment. The bending moment causes the projection to rotate, which tears an opening in the air chamber wall. The crack or break in the air chamber wall is primarily due to tensile stresses in the air chamber wall that arise from the bending moment or the rotation of the projection. Opening the air chamber wall activates the ventilation function of the connection piece.

The air chamber can be connected to an air duct that runs through the welded part. The air duct is preferably connected to an air pipe or an air hose. An end of the air pipe facing away from the air duct ends in an area of the chamber that is remote from the connection piece. When the dosing system is in use, this remote area can represent the upper area of the chamber. When the preparation is dispensed, air can flow into the upper area of the chamber. The air required for ventilation flows through the torn opening in the air chamber wall, through the air duct connected to the air chamber and through the air pipe into the chamber. Negative pressure in the chamber, which makes dispensing difficult, can thus be avoided.

If the container is not yet connected to the dosing device, the preparations in the chambers are completely separated from the environment due to the intact membrane and the undamaged air chamber wall. Only when the connector and connection holder are connected to one another is dosing with a ventilation function possible via the air chamber and the torn membrane.

A finger ring can be attached to the base body, which can be moved from a starting position into an active position, wherein in the active position the finger ring is designed to be gripped by a human finger in order to introduce a tensile force into the base body, by means of which the connecting piece can be separated from the connecting receptacle.

In one embodiment, the finger ring can be rotated from the starting position about a pivot axis into the active position. Preferably, a hinge in the form or type of a film hinge is provided between the finger ring and the base body, which is integrally formed on the finger ring and the base body.

The finger ring can be attached to the base body by two connecting bars, whereby the two connecting bars can define the pivot axis around which the finger ring can be moved out of the Starting position can be swiveled into the active position. A swivel angle between the starting position and the active position can be 80 to 100°, preferably approx. 90°.

Preferably, the finger ring forms a tab with a closed peripheral area with the base body and the two connecting bars. The closed peripheral area is stable and can absorb high tensile forces.

A pressure plate can be formed on the base body to accommodate a human finger, the pressure force of which can connect the connector to the connector holder. In the starting position, the finger ring can surround the pressure plate and lie essentially in the same plane as the pressure plate. While the finger ring in the active position is used to pull the cover part out of the connector holder in order to release the connection between the connector and the connector holder, the pressure plate is used to press the plug-in part of the base body into the connector holder. In this embodiment, the force required to establish the connection between the connector and the connector holder can therefore also be directed directly to the connector.

In one embodiment, the pressure plate is arranged coaxially to the membrane. This means that the pressure force for piercing the membrane can be applied directly above the membrane without lateral offset. The membrane can lie in a plane that extends parallel to the plane of the pressure plate.

The pressure plate can be slightly curved inwards (concave). The inward curvature prevents the finger from slipping when the pressure is applied. In one embodiment, the diameter of the pressure plate is 10 to 20 mm. In the embodiment with the finger ring surrounding the pressure plate, the effective contact surface for the finger is increased, since part of the pressure force can now also be applied to the finger ring.

• 1 ein Dosiersystem;
• 2 schematisch im Schnitt das Dosiersystem;
• 3 schematisch einen erfindungsgemäßen Behälter für das Dosiersystem;
• 4 diverse Ansichten eines Anschlussstücks des erfindungsgemäßen Behälters (4A bis 4B);
• 5 weitere Ansichten des Anschlussstücks der 4 (5A bis 5D);
• 6 zwei Schnittansichten des Anschlussstücks der 4 und 5 (6A und 6B); und
• 7 das Anschlussstück in einer weiteren Schnittansicht mit Teilen des Dosiergeräts.

The invention is explained in more detail with reference to the embodiments shown in the drawing. They show:

• 1 a dosing system;
• 2 schematic cross-section of the dosing system;
• 3 schematically shows a container according to the invention for the dosing system;
• 4 various views of a connecting piece of the container according to the invention ( 4A to 4B) ;
• 5 further views of the connector of the 4 ( 5A to 5D );
• 6 two sectional views of the connector of the 4 and 5 ( 6A and 6B) ; and
• 7 the connector in another sectional view with parts of the dosing device.

1 shows a dosing system 1 comprising a dosing device 10 and a container. The container is housed within a flat housing 11 of the dosing device 10 and in 1 not recognizable. In the 2 and 3 the dosing system 1 with the dosing device 10 and with the container designated 40 is shown schematically.

The dosing system 1 can be placed in the interior of a dishwasher and is designed to dispense one or more preparations located in the container 40 during a wash cycle. The dosing system 1 can exchange signals, data, control commands, etc. with the dishwasher so that the preparations can be dispensed precisely in terms of time and quantity.

Like the 1 and 2 can be seen, the housing 11 of the dosing device 10 has a front wall 12 and a rear wall 13. The front wall 12, which is rectangular in its basic shape, and the rear wall 13, which is also rectangular in its basic shape, extend from a base 14 to an upper housing edge 15. In the vicinity of the upper housing edge 15, a film hinge 16 is provided between the front wall 12 and the rear wall 13, so that the housing 11 can be opened and a container compartment 17 (see 2 ) of the dosing device 10 is opened. The container compartment 17 serves to accommodate the container 40. When the housing 11 is opened, the container 40 can be removed from the container compartment 17 in order to replace it with another container. The container 40 can be designed in such a way that it can hold the preparation or preparations in such a quantity that they are sufficient for several rinse cycles (for example for 20 to 30 rinse cycles). After emptying, the container 40 can be replaced with a filled container.

Out of 1 It can also be seen that a first recess 18 and a second recess 19 are provided on the rear wall 13. In the following, only the first recess 18 will be discussed in more detail. Since the second recess 19 is identical to the first recess 18 in terms of its design, the statements regarding the first recess apply. The same applies to the second recess 19.

The first recess 18 starts at the base 14 and extends in the direction of the upper housing edge 15. The recess 18 is designed as an elongated, channel-like or groove-like recess, wherein a length in the longitudinal direction of the recess (direction from the base 14 to the upper housing edge 15) is significantly greater than a width of the recess transverse to the longitudinal direction. The first recess 19 has a groove base 20, the distance of which from the surface in which the rear wall 13 lies defines a depth of the first recess 18. Starting from a lower, open end 21, which is located on the base 14, to an upper, closed end 22, the depth is reduced. Accordingly, the depth at the lower end 21 is greater than the depth in the area of the upper end 22. Starting from the lower end 21, the groove bottom 20 initially runs in a straight line (i.e. the depth is initially constant there) and then merges into a curved section with decreasing depth.

The two recesses 18, 19 each serve to accommodate a holding rod that stands approximately vertically upwards or is slightly inclined to the vertical, of a plate holder in a crockery drawer that can be pulled out of the interior to put dishes in and take them out. The plate holder usually has two parallel rows of holding rods that are a certain distance apart within a row (bar spacing). The distance between the two recesses 18, 19 corresponds to the distance between the two rows, so that the dosing device 10 with the container 40 located in the housing 11 can be placed in a plate compartment of the plate holder like a plate. The dosing device 10 is supported like a plate on the holding rods that form the plate compartment. Due to the special course of the groove base 20 with the depth reducing towards the upper end 22, the dosing device 10 can be placed in a plate holder in which the bar spacing is small and the holding rods are of medium length. On the other hand, the dosing device 10 can also be placed in a plate holder where the bar spacing and the length of the holding bars are large. In the latter case, the dosing device is supported by the upper end of the holding bar in the upper area of the recess 18, i.e. where the depth of the recess is small. As a result, even with a large bar spacing, the dosing device 10 stands upright in the plate holder and does not block adjacent plate compartments by being too tilted.

The height (distance between base 14 and upper edge 15) and the width of front wall 12 and rear wall 13 correspond to the diameter of a larger dinner plate. For example, the housing 11 can have a height of 200 to 280 mm. The width of the housing 11 can be 200 to 280 mm. The ratio of height to width can be 0.8 to 1.2.

Again 1 As can also be seen, the housing 11 has a thickness which is greatest in the area of the bottom 14 and then decreases slightly towards the upper edge 15. A maximum thickness of the housing, preferably in the area of the bottom 14, can be between 20 and 28 mm. In the schematic representation of the 2 the housing 11 is shown simplified with a constant thickness.

While 1 the dosing system 1 standing on the floor 14, shows 2 the dosing system 2 in a lying position, with the rear wall 13 pointing downwards. In this lying position, the housing 11 can be opened by pivoting the front wall 12 about the pivot axis of the film hinge 16 (in the illustration of the 2 the pivot axis extends perpendicular to the plane of the drawing). When the front wall 12 is opened, the container 40 can be removed from the container compartment 17. How this removal of the container 40 takes place and how a new container can be reconnected to the dosing device will be explained in more detail later.

From the 3 it becomes clear that the container 40, which is only shown schematically, has several chambers. In the exemplary embodiment shown, there are three chambers 41, 42, 43. Each chamber is used to hold a preparation, which can be, for example, an alkaline cleaning preparation, an enzymatic cleaning preparation, a rinse aid or a fragrance. Each chamber is assigned a connecting piece 44, the structure of which does not differ from the structure of the other connecting pieces 44. The chambers 41, 42, 43 are approximately the same size, but they can also differ significantly from one another in terms of their volume and shape. For example, one of the chambers can be designed to be twice as large for a preparation that is dispensed in twice the amount in one wash cycle compared to the other preparations, so that when the container needs to be replaced, all chambers are as completely emptied as possible or at least only very small residual amounts are left.

The chambers 41, 42, 43 are delimited by two housing halves or chamber walls 45, 46. Each housing half 45, 46 forms three shells or troughs, which form a chamber with the opposite shell. To produce the housing halves 45, 46, a (folded) ted) plastic film can be used, which is drawn or blown into corresponding deep-drawing molds. The housing halves 45, 46 are welded together at a peripheral edge 47 and also at intermediate webs 48 between the individual chambers 41, 42, 42. The connecting pieces 44 are arranged in a section 47a of the edge 47 between the two housing halves 45, 46. These are inserted between the housing halves 45, 46 before the section 47a is welded and then welded to the housing halves 45, 46 in a liquid-tight manner. The sealing/welding of the section 47a to the connecting pieces 44 is expediently only carried out after the chambers 41, 42, 43 have been filled with the respective preparations. However, during filling, the housing halves 45, 46 are already welded together at the edge 47 (except for the gate 47a) and at the intermediate webs 48. Thermoforming enables thin walls. The amount of material required is very low. The housing halves 45, 46 can be made of polypropylene (PP), for example.

The dosing device 10 has a connection receptacle 23 for each connection piece 44 (see 2 , which shows one of the connection receptacles). When the container 40 is inserted in the housing 11 of the dosing device 10, the connection piece 44 and the connection receptacle 23 form a liquid-tight connection so that the preparation can pass from the chamber into a dosing chamber of the dosing device 10 assigned to the respective chamber. The dosing chamber and a dosing valve are in 2 not shown. Only a dosing compartment 24, which accommodates the dosing chamber and the dosing valve and is integrated in the rear wall 13, is in 2 The dosing compartment 24 has a dosing opening 25 for each chamber/dosing valve, through which the preparation from the relevant chamber then reaches the interior of the dishwasher via the connection piece 44/connection receptacle 23. It should be noted that when the dosing system 1 is in use, the base 14 points downwards so that the preparations from the chambers 41, 42, 43 can flow out of the relevant dosing opening 25 due to gravity when the dosing valve is open.

The 4 to 7 show the connector 44 in its own position in different views. 4 shows two perspective views ( 4A and 4C and a chamber-side view ( 4B) and a side view (4D). 5A shows the connector 44 from below, 5C from above in plan view. 5B shows a view from the front. 5D shows another side view. 6A is a horizontal longitudinal section through the connecting piece 44. 6B shows the connector 44 in a vertical longitudinal section, while 7 shows a cross-section that runs perpendicular to the two sections 6A, 6B. In addition, 7 indicated parts of the dosing device.

The connector 44 has a base body 49 with a welded part 50 and a plug-in part 51. The welded part 50 forms an inflow channel 52 through which the preparation from the chamber passes into the connector 44. The plug-in part 51 forms an outflow channel 53 through which the preparation flows from the connector 44 into the connection receptacle 23 (see 6 and 7 ). Between the inflow channel and the outflow channel, a connecting channel 54 is provided which connects the inflow channel 52 and the outflow channel 53. When the connecting piece 44 is new, the inflow channel 52 and the outflow channel 53 or the connecting channel 54 are separated from one another by a membrane 55. In other words, when the container 40 is new, the preparation from the chamber 41, 42, 43 cannot get into the outflow channel 53. The membrane 55 therefore protects the preparation in the chamber from environmental influences and also prevents it from leaking out.

A longitudinal axis 56 of the inflow channel 52 is at a right angle to a longitudinal axis 57 of the outflow channel 51. The connecting channel 54 is essentially aligned with the inflow channel 52. The connecting channel 54 is limited at the top by a round, slightly inwardly curved pressure plate 58. The pressure plate 58 serves to accommodate a human finger in order to build up a pressure or a pressure force in order to press the connection piece 44 with the plug-in part 51 into the connection receptacle 23 of the dosing device 10. A central axis of the pressure plate 58 coincides with the longitudinal axis/central axis 57 of the plug-in part 51 or has only a very small offset. The resulting force of the finger force applied to the pressure plate 58 acts vertically directly above the plug-in part 51. In the 4D , 6B and 7 the resulting force is designated F _D. Several smaller openings in the pressure plate 58 can be provided in order to save material and to simplify the injection molding of the connecting piece 44.

A finger ring 59 is attached to the base body 49. The attachment of the finger ring 59 to the base body 49 is made via two spaced connecting webs 60 (see for example 5C and 6A) . Due to the connecting webs 60, which are each attached to a circumferential end of the finger ring 59, the finger ring 59 has a closed circumference. The finger ring 59 extends in the circumferential direction over an angular range of approximately 270°. In the circumferential direction, in the middle between the two end connecting webs 60, there is also a fixing web 61 between the finger ring 59 and pressure plate 58 are provided to hold the finger ring 59 in the position shown.

The position shown is a so-called starting position of the finger ring 59. In this starting position, the finger ring 59 lies in the same plane as the pressure plate 58 and represents a certain radial extension of the pressure plate 58. From this starting position, the finger ring 59 can be pivoted into an active position. For this purpose, a gripping tab 62 is provided in the immediate vicinity of the fixing web 61, by means of which the finger ring 59 can be raised relative to the pressure plate 58, but the fixing web 61 must be broken. Further lifting of the gripping tab 62 leads to a pivoting movement of the finger ring 59 about a pivot axis 63 (see dotted line in the 5C and 6A) The pivot axis 63 is defined by the position of the connecting webs 61, which are deformed during the pivoting movement and form a type of film hinge. In comparison to the fixing web 61, the connecting webs 60 are significantly stronger and can absorb tensile forces that are transmitted through the finger ring 59 into the base body 49.

In 5D the active position of the finger ring 59 is indicated by the dashed line 59'. In this position, a human finger can be hooked through the finger ring 59 or 59'. This makes it possible to exert a comparatively large pulling force on the base body 44 and in particular on the plug-in part 51. The resulting force of the hooked finger is in 5D designated Fz. The overview of the 4D and 5B show that the resulting force FD for establishing the connection between the connector 44 and the connector receptacle 23 and the force FZ for separating this connection are opposite. The connection can be established and separated by a linear movement which is directed perpendicularly to the front wall 12 and the rear wall 13, respectively.

With the finger ring 59 in the active position, the connector 44 can be pulled out of the connector 23. This makes it possible to remove the container 40 from the 2 in the housing 11 inserted position from the dosing device 10. It is not necessary to introduce the forces required for this into the container 40 via the rather unstable housing halves 45, 46.

To remove the container 40, the three connection pieces 44 can first be lifted one after the other out of the respective connection receptacles using the finger ring so that they rest on the connection receptacles with practically no resistance and without any insertion force. The container 40 can then be removed from the housing 11 either using one finger ring or using two finger rings at the same time.

In addition to the inflow channel 52 for the preparation, the welded piece 50 also forms an air channel 64 which opens into a closed air chamber 65 in the base body 44. The air chamber 65 is arranged next to the connecting channel 54 (see 6A and 7 ). As can be seen from 6A As can be seen, an air hose 66 can be inserted into the open end of the air duct 64. The length of the air hose 66 is dimensioned such that the free end of the air hose, i.e. the end that is not inserted into the air duct 64, is located at one end of the chamber that is opposite the connector 44. In 3 the air hose 66 is only indicated by the dashed line for the chamber 42. In the operating position of the dosing system 1, i.e. with the bottom 14 of the dosing device 10 facing downwards, the air hose 66 ends with its open end in the upper area of the chamber 42. Such an air hose is also provided for the connecting pieces 44 of the other two chambers 41, 43, but this is not the case in 3 is not shown.

The closed air chamber 65 is enclosed by an air chamber wall 67. An outward-facing projection 68 is formed on the air chamber wall 67. At a root of the projection 68, the air chamber wall 67 has a predetermined breaking point 69 with reduced wall thickness and a thin hinge point or connection point 70. When inserting the plug-in part 51 into the connection receptacle 23, the membrane 55 is first pierced by a hollow mandrel 26 of the connection receptacle 23 (see 7 ). If the plug-in part 51 is pressed further into the connection receptacle 23, an abutment 27 of the connection receptacle comes into contact with a contact 71 of the projection 68. The contact 71 is provided at a free end of the projection 68.

The system 71 has a distance 72 from the predetermined breaking point 69 and the connection point 70. Due to the force acting on the projection 68 from the fixed abutment 27 and due to the distance 72, a bending moment acts on the root of the projection 68, which leads to tensile stresses in the area of the predetermined breaking point 69. If the tensile stresses become too great, the air chamber wall 67 tears in the area of the predetermined breaking point 69. The projection 68 rotates around the thin connection point 70 in the illustration of the 7 anti-clockwise upwards, without the projection 68 completely detaching from the base body 44. Due to the crack or break at the predetermined breaking point 69, an exchange of air between the environment and the air chamber 65 and thus an exchange of air between the environment and the chamber is possible. The ventilation of the chamber in question is activated.

The connector 44 and the connector removal 23 are designed in such a way that when the plug-in part 51 is inserted into the connector removal 23, the membrane 55 is pierced before the ventilation of the chamber is activated, i.e. before the air chamber wall 67 tears. The hollow mandrel 26 and the abutment 27 of the connector receptacle 23 as well as their relative height to each other are in 7 only schematically indicated. According to 7 the beginning of the piercing of the membrane 55 is imminent, while there is still a gap between the abutment 27 and the attachment 71 of the projection 68. Only when the connecting piece 44 is pressed further into the connection receptacle 23 does the projection 68 strike the abutment 27.

List of reference symbols

1

Dosing system

10

Dosing device

11

Housing

12

Front wall

13

Back wall

14

Floor

15

upper housing edge

16

Film hinges

17

Container compartment

18

first recess

19

second recess

20

Groove bottom

21

lower end

22

top end

23

Connection holder

24

Dosing compartment

25

Dosing opening

26

Hollow mandrel

27

Abutment

40

container

41

chamber

42

chamber

43

chamber

44

Connector

45

Housing half / chamber wall

46

Housing half / chamber wall and

47

Rands (Section 47a)

48

Intermediate bridge

49

Base body

50

Welded part

51

Plug-in part

52

Inflow channel

53

drainage channel

54

Connecting channel

55

membrane

56

Longitudinal axis

57

Longitudinal axis

58

Pressure plate

59

Finger ring (59' finger ring in active position)

60

Connecting bridge

61

Fixing bars

62

Grip tab

63

Swivel axis

64

Air duct

65

Air chamber

66

Air hose / air pipe

67

Air chamber wall

68

head Start

69

Predetermined breaking point

70

Connection point / hinge point

71

Attachment

72

Distance

QUOTES INCLUDED IN THE DESCRIPTION

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

Cited patent literature

• EP 2296520 B1 [0002, 0003]

Claims (14)

Container (40) for a dosing system (1) which can be positioned in the interior of a dishwasher and comprises a dosing device (10) through which at least one preparation can be dosed into the interior, wherein the container (40) has at least one chamber (41, 42, 43) for receiving the preparation and a connecting piece (44) associated with the chamber (41, 42, 43), which is connected to the chamber (41, 42, 43) and can be connected to a connection receptacle (23) of the dosing device (10) to form a connection between the chamber (41, 42, 43) and the dosing device (10), and wherein the connecting piece (44) has a membrane (55) which is closed in a new state and is designed to be opened when the connecting piece (44) is connected to the connection receptacle (23), characterized in that the connecting piece (44) has a base body (49) to which the membrane (55) is integrally formed, wherein the base body (49) and the membrane (55) are made of the same material. Container (40) to Claim 1 , characterized in that a wall thickness of the membrane (55) is 0.01 to 0.5 mm, preferably 0.04 to 0.2 mm and very preferably 0.08 to 0.12 mm. Container (40) to Claim 1 or 2 , characterized in that the membrane (55) is made of polyolefin which is filled with a filler. Container (40) to Claim 3 , characterized in that the membrane (55) is made of polyolefin which is filled with calcium carbonate with a weight proportion of 0.1 to 20, preferably 2 to 8%. Container (40) to Claim 3 or 4 , characterized in that a grain diameter of the filler is smaller than the wall thickness of the membrane (55). Container (40) according to one of the Claims 1 until 5 , characterized in that the base body (49) has a welded part (50) with an inflow channel (52), wherein the welded part (50) is sealingly attached to a chamber wall (45, 46) of the chamber (41, 42, 43) and the inflow channel (52) is connected to the chamber (41, 42, 43). Container (40) according to one of the Claims 1 until 6 , characterized in that the base body (49) has a plug-in part (51) with a drainage channel (53), wherein the plug-in part (51) can be inserted into the connection receptacle (23). Container (40) to Claim 6 and Claim 7 , characterized in that the membrane (55) is arranged between the inflow channel (52) and the outflow channel (53). Container (40) according to one of the Claims 1 until 8th , characterized in that the base body (49) has an air chamber (65) with an air chamber wall (67) for ventilating the chamber (41, 42, 43), wherein a projection (68) is formed on the air chamber wall (67) and has a contact surface (71) spaced apart from the air chamber wall (67) for an abutment (27) of the connection receptacle (23), so that a force which acts on the contact surface (71) of the projection (68) when the connection piece (44) and the connection receptacle (23) are connected generates a bending moment, by means of which the projection () is rotated and an opening is torn in the air chamber wall (67). Container (40) according to one of the Claims 1 until 9 , characterized in that a finger ring (59) is attached to the base body (49), which can be moved from a starting position into an active position, wherein in the active position the finger ring (59) is designed to be gripped behind by a human finger in order to introduce a tensile force into the base body (49), by means of which the connecting piece (44) can be separated from the connecting receptacle (23). Container (40) to Claim 10 , characterized in that the finger ring (59) is attached to the base body (49) by two connecting webs (60), wherein the two connecting webs (60) define a pivot axis about which the finger ring (59) can be pivoted from the starting position into the active position. Container (40) according to one of the Claims 1 until 11 , characterized in that a pressure plate (58) for receiving a human finger is formed on the base body (49), by the pressure force of which the connecting piece (44) can be connected to the connection receptacle (23). Container (40) to Claim 12 with one of the Claims 10 or 11 , characterized in that the finger ring (59) in the starting position surrounds the pressure plate (58) and lies substantially in the same plane as the pressure plate (58). Container (40) to Claim 12 or 13 , characterized in that the pressure plate (58) is arranged coaxially to the membrane (55).

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