EP1724208B1 - Multi-chamber dispenser - Google Patents

Description

The invention relates to a multi-chamber dispensing device for dispensing a mixture consisting of a plurality of substances according to the preamble of patent claim 1.

Such a multi-chamber dispenser is from the document US 4,240,566 known. This multi-chamber dispenser comprises a receiving unit having two chambers aligned parallel to one another and each having an open first end for insertion of a piston and a second end provided with an exit opening. Downstream of the outlet opening of the chambers, the receiving unit has a neck region. Furthermore, an output unit is provided which has an output channel and an adapter portion for fluid-tight connection to the neck region of the receiving unit. In order to position the dispensing unit axially relative to the receiving unit, an adjusting ring is provided, which is rotatably mounted on the receiving unit and engages around the receiving unit.

Another multi-chamber dispenser is from the EP 1 203 593 A1 known and designed for single use as a disposable item.

The invention has for its object to provide a suitable for repeated use multi-chamber dispensing device, which is easy to handle and is inexpensive to produce.

This object is achieved by the multi-chamber dispensing device having the features of patent claim 1.

The subject of the invention is therefore a multi-chamber dispensing device for dispensing a mixture consisting of a plurality of substances, comprising a receiving unit a plurality of chambers aligned in parallel with each other, each having an open, first end for insertion of a piston and a second end provided with an exit port, and a neck portion located downstream of the exit ports of the chambers. Furthermore, the multi-chamber dispenser includes an output unit having an output channel and an adapter portion for fluid-tight communication with the neck portion of the receiving unit. According to the invention, a collar for axial positioning of the dispensing unit is provided, which is rotatably mounted on the receiving unit and engages the dispensing unit.

Thus, a multi-chamber dispensing device is provided with an adjusting ring, by means of which an axial positioning of the dispensing unit can take place, so that the dispensing unit can be displaced from the receiving unit in the axial direction and replaced by a new dispensing unit. Furthermore, the adjusting ring can, for example, act on the dispensing unit in such a way that the dispensing unit is moved between a closed position in which a fluid flow between the chambers of the receiving unit, which is generally substantially in the form of a multi-chamber syringe body, and the dispensing channel of the dispensing unit is blocked, and an dispensing position can, in which a fluid flow between the chambers of the receiving unit and the output channel of the output unit is released.

The dispensing unit may be separated from the receiving unit immediately after completion of a use application of the multi-chamber dispenser and replaced with a new dispensing unit so that no substances are downstream of the exit openings of the chambers of the receiving unit more are available. With the removal of the dispensing unit also adhering thereto, already leaked from the chambers of the receiving unit shares of the otherwise stored in the chambers substances are eliminated. The newly inserted dispensing unit can in turn lock by appropriate selection of the rotational position of the adjusting ring a fluid flow between the chambers of the receiving unit and the output channel of the output unit, up to the time at which the collar is rotated angularly and the output unit can be positioned so in that a fluid flow between the chambers of the receiving unit and the output channel of the dispensing unit is released. The substances contained in the individual chambers can be mixed downstream of the outlet openings of the chambers and upstream of the discharge channel.

The chambers of the receiving unit may have different or equal volumes, so that by appropriate design of the respective outlet openings, a mixing ratio between the substances separately held in the chambers can be adjusted.

In a preferred embodiment of the multi-chamber dispensing device according to the invention, the adjusting ring has at least a first, a rest position representing rotational position in which by means of the output unit, a substance flow between the chambers and the output channel is blocked, and a second, an output position representing rotational position in which the substances from the chambers of the receiving unit by a piston pressure in the output channel can be conveyed and applied over this. A user of the multi-chamber dispensing device according to the invention can thus actuate the adjusting ring in a defined manner, which facilitates handling of the multi-chamber dispenser.

In order to provide the user with the respective positions of the adjusting ring also haptically, the adjusting ring preferably engages in the rest position and in the dispensing position on a latching device. This consists for example of a formed on the receiving portion locking lug, which can engage with recesses of the adjusting ring. A design of a locking lug on the adjusting ring is conceivable.

In a special embodiment of the multi-chamber dispensing device according to the invention, the adjusting ring is mounted on a plate extending transversely to the longitudinal axis of the chambers, which is formed in the region of the second end of the receiving unit. There is thus a bearing plate for the adjusting ring available that allows accurate axial positioning of the adjusting ring.

In order to ensure a captive storage of the adjusting ring on the receiving unit, the adjusting ring may have an annular groove, in which engages the outer edge region of the front panel.

In order to facilitate the separation of the dispensing unit from the receiving unit, the adjusting ring comprises at least one ramp, which cooperates with at least one actuating arm, which is supported on the adjusting ring, so that the output unit undergoes an axial offset upon rotation of the adjusting ring. By way of example, the ramp is designed such that a rotation of the adjusting ring in a clockwise or counterclockwise direction makes it possible to reduce the output unit from the receiving unit. Alternatively, the ramp can also be formed on the output unit, in which case the adjusting ring slides along the ramp as it rotates with an area formed therefor.

In particular, the end region of the ramp facing away from the chambers defines a third rotational position of the adjusting ring which represents an ejection or removal position, in which the dispensing unit can be removed from the neck region of the receiving unit in a simple manner.

In a special embodiment of the multi-chamber dispensing device according to the invention, the dispensing unit is moved by rotation of the adjusting ring by means of the ramp from the neck region of the receiving unit. The output unit is inserted in this case so before appropriate actuation of the adjusting ring in the neck region of the receiving unit.

The ramp of the adjusting ring may extend with respect to the axis of the substantially cylindrical neck region of the receiving unit over an angular range of, for example, between about 90 ° and 160 °.

In order to ensure reliable operation of the adjusting ring, it is advantageous if the dispensing unit is mounted non-rotatably in the neck region. The non-rotatable mounting can be achieved, for example, in that the neck region has an elliptical cross-section and / or a rotation lock for the dispensing unit is arranged in the neck region. The rotation lock is formed for example from a engaging in a recess of the output unit projection. Such a design also facilitates a defined connection of the dispensing unit with the neck region of the receiving unit.

In order to ensure the proper interaction between the adjusting ring and the output unit, at least one actuating arm or a control flap can be formed on the output unit, which is supported on the adjusting ring. Preferably, two offset by 180 ° to each other control arms are formed on the output unit, which cooperate in each case with a correspondingly formed portion of the adjusting ring.

Preferably, a transverse support is formed on the output unit, from which the actuating arm or the adjusting tab protrudes in the direction of the chambers of the receiving unit.

In a special embodiment of the multi-chamber dispensing device according to the invention, the adjusting ring is designed so that the actuating arm rests in the rest position representing the first rotational position on a shoulder of the adjusting ring. Rotation of the adjusting ring to the second output position representing rotational position then releases the dispensing unit so that it can be manually pressed in the direction of the chambers of the receiving unit, which in turn can release fluid flow between the chambers and the dispensing passage of the dispensing unit. A further rotation of the adjusting ring taking place in the same direction of rotation then allows the actuating arm to slide with its front side along the ramp of the adjusting ring, which in turn causes an axial displacement of the dispensing unit in the direction away from the chambers, so that the dispensing unit either ejected or simply from the Recording unit can be removed.

In order to secure the dispensing unit against unintentional release from the receiving unit, at least one stop is provided on the outer wall of the neck area for the actuating arm arranges, which preferably cooperates with a transverse web of the actuator arm. The stop can secure the dispensing unit in the rest position and / or in the dispensing position of the adjusting ring. For example, two stops arranged in succession in the axial direction of the multi-chamber dispensing device, each of which is assigned to an operating position of the dispensing unit, are formed for each actuating arm. In order to facilitate placement of the dispensing unit on the neck area or a displacement of the dispensing unit from the blocking position into the passage position, the stop or the stops on the side facing away from the chambers of the receiving unit may have a bevel.

In order to prevent unwanted mixing of the substances in the chambers of the receiving unit downstream of the outlet openings, the dispensing unit is preferably provided with a closing unit for the outlet openings of the chambers.

The closing unit may comprise, for each of the chambers, a closure plug associated with the respective outlet opening. The closing unit is therefore a multi-plug closure.

The closure plugs can be designed so that they release a substance flow from the chambers of the receiving unit to an in the open position, ie in the dispensing position of the adjusting ring to a provided for example with a static mixer mixing chamber, which is arranged in the output unit upstream of the output channel.

The sealing plugs may for this purpose be designed such that they are each provided with a transverse channel which is connected to a sacklock-like axial channel of the respective sealing plug, which leads to the mixing chamber.

The closing unit may further comprise a plate-shaped body (46, 146) rotatably supported on the side of the dispensing unit facing the receiving unit. This allows easy positioning of the closing unit with respect to the outlet openings of the chambers of the receiving unit in the circumferential direction.

On the output unit and the plate-shaped body of the closing unit locking means may be formed which cooperate such that the output unit and the closing unit can be locked together in a predetermined angular position.

Further, a transversely projecting lug may be integrally formed on the plate-shaped body of the Schleißeinheit, which cooperates with a formed in the interior of the neck region longitudinal groove so that the closing unit can be used only in a predetermined angular position in the neck region in which the sealing plug of the closing unit with each associated outlet openings of the chambers are aligned.

Further advantages and advantageous embodiments of the article according to the invention are the description, the drawings and the claims removed.

• Fig. 1 eine teilweise geschnittene Seitenansicht eines Ausführungsbeispiels einer Mehrkammerausgabevorrichtung nach der Erfindung im geschlossenen Zustand;
• Fig. 2 eine Fig. 1 entsprechende Ansicht der Mehrkammerausgabevorrichtung, jedoch im aktivierten Zustand;
• Fig. 3 eine Fig. 1 entsprechende Ansicht der mit Mehrkammerausgabevorrichtung, jedoch bei der Entfernung einer Ausgabeeinheit;
• Fig. 4 einen Längsschnitt durch eine Aufnahmeeinheit der Mehrkammerausgabevorrichtung;
• Fig. 5 eine Seitenansicht der Aufnahmeeinheit, die gegenüber Fig. 4 um 90° gedreht ist;
• Fig. 6 eine Draufsicht auf die in Fig. 4 dargestellte Aufnahmeeinheit;
• Fig. 7 eine Seitenansicht einer Kolbeneinheit der Mehrkammerampulle;
• Fig. 8 eine Draufsicht auf die in Fig. 7 dargestellte Kolbeneinheit;
• Fig. 9 einen Längsschnitt einer Ausgabeeinheit der Mehrkammerausgabevorrichtung;
• Fig. 10 eine Draufsicht auf die in Fig. 9 dargestellte Ausgabeeinheit;
• Fig. 11 eine Draufsicht auf einen Stellring der Mehrkammerausgabeeinheit;
• Fig. 12 eine Seitenansicht des in Fig. 11 dargestellten Stellrings;
• Fig. 13 einen Längsschnitt durch eine Ausgabeeinheit einer zweiten Ausführungsform einer Mehrkammerausgabevorrichtung nach der Erfindung;
• Fig. 14 eine Seitenansicht der Ausgabeeinheit nach Fig. 13;
• Fig. 15 eine Seitenansicht durch eine Schließeinheit, die mit der in Fig. 13 dargestellten Ausgabeeinheit verbindbar ist;
• Fig. 16 eine Draufsicht auf die Schließeinheit nach Fig. 15; und
• Fig. 17 einen Längsschnitt durch die Schließeinheit nach Fig. 15.

Two embodiments of the multi-chamber dispenser according to the invention are schematic in the drawing shown simplified and are explained in more detail in the following description. It shows:

• Fig. 1 a partially sectioned side view of an embodiment of a multi-chamber dispenser according to the invention in the closed state;
• Fig. 2 a Fig. 1 corresponding view of the multi-chamber dispensing device, but in the activated state;
• Fig. 3 a Fig. 1 corresponding view of the multi-chamber output device, but in the removal of an output unit;
• Fig. 4 a longitudinal section through a receiving unit of the multi-chamber output device;
• Fig. 5 a side view of the receiving unit, opposite Fig. 4 rotated by 90 °;
• Fig. 6 a top view of the in Fig. 4 illustrated receiving unit;
• Fig. 7 a side view of a piston unit of the multi-chamber ampule;
• Fig. 8 a top view of the in Fig. 7 illustrated piston unit;
• Fig. 9 a longitudinal section of an output unit of the multi-chamber output device;
• Fig. 10 a top view of the in Fig. 9 illustrated output unit;
• Fig. 11 a plan view of a collar of the multi-chamber output unit;
• Fig. 12 a side view of the in Fig. 11 illustrated adjusting ring;
• Fig. 13 a longitudinal section through an output unit of a second embodiment of a multi-chamber dispenser according to the invention;
• Fig. 14 a side view of the output unit after Fig. 13 ;
• Fig. 15 a side view through a closing unit, with the in Fig. 13 shown output unit is connectable;
• Fig. 16 a plan view of the clamping unit according to Fig. 15 ; and
• Fig. 17 a longitudinal section through the closing unit after Fig. 15 ,

In the FIGS. 1 to 12 a two-chamber ampule 100 is shown, which is composed essentially of four structural units, namely a receiving unit 10, a piston unit 20, an output unit 30 and a collar 40.

In particular the FIGS. 4 to 6 It can be seen that the container-like receiving unit 10 comprises two parallel juxtaposed, tubular chambers 12 and 14 which extend in the longitudinal direction of the container 10. The chambers 12 and 14 are open at their first ends shown in the drawing below each over their entire cross section. On the outer sides of the first ends of the chambers 12 and 14, a transverse in the radial direction extending rear plate 16 is formed. The first ends facing away from the second ends of the chambers 12 and 14 are connected to each other via a molded front plate 18. In the front panel 18, an outlet opening 11 for the chamber 12 and an outlet opening 13 for the chamber 14 are formed.

On the side facing away from the chambers 12 and 14, a neck portion 15 is formed on the front plate 18, which surrounds the outlet openings 11 and 13 and is formed substantially cylindrical. The axis of the neck area 15 is arranged parallel to the axes of the chambers 12 and 14. In the present embodiment, the chamber 14 has a four times larger cross section than the chamber 12. Accordingly, the outlet opening 13 has a four times larger cross-section than the outlet opening 11. Alternatively, the chambers 12 and 14 but also with the same cross-sections or with any other cross-sectional ratios be educated. The same applies to the outlet openings 11 and 13.

As in particular the FIGS. 7 and 8 can be seen, the piston unit 20 comprises two piston rods 22 and 24, the rear ends are connected to each other via a printing plate 26. At the front end of the piston rod 22, a piston 21 is formed for the chamber 12 of smaller diameter. At the front end of the piston rod 24, a piston 23 is formed for the chamber 14 of larger diameter. The diameters of the pistons 21 and 23 correspond to the inner diameters of the chambers 12 and 14, respectively. The pistons 21 and 23 can be inserted into the rear open ends of the chambers 12 and 14 and displaced therein synchronously and in a fluid-tight manner.

The particular in the FIGS. 9 and 10 illustrated output unit 30 includes an adapter portion 31 for coupling with the receiving unit 10 and a pipe section 33 in which an axial output channel 33 is formed, which leads to the free end face of the pipe section 32. The adapter portion 31 has a cylindrical portion with an outer diameter corresponding to the inner diameter of the neck portion 15 of the receiving portion 10 and so into the open end of the neck portion 15 is inserted and fluid-tight manner.

Furthermore, the dispensing unit 30 comprises in the region of the adapter section 31 a closing unit 35 for the outlet openings 11 and 13 of the chambers 12 and 14 of the receiving unit 10. The closing unit 35 is made of a base plate 36 and two projecting from this in the axial direction in the direction of the receiving unit 10 Closing plug 37 and 38 are formed, whose outer diameter correspond respectively to that of the respective associated outlet opening 11 and 13 respectively.

Between the base plate 36 and the discharge channel 33 a substantially frusto-conical mixing chamber 39 is arranged, open into the axial channels 71 and 72 of the sealing plug 37 and 38. The axial channels are each formed like a blind hole and connected to a transverse channel 73 and 74 of the respective sealing plug 37 and 38, respectively.

Furthermore, the output unit 30 comprises a cross member 75, from which with respect to the axis of the discharge channel 33 offset by 180 ° to each other offset actuating arms 76 and 77 in the direction of the chambers 12, 14 of the receiving unit 10. The actuating arms 76 and 77 have at their free ends in each case a radially inwardly projecting transverse web or projection 78 and 79, which cooperate with two arranged on the circumference of the neck portion 15 of the receiving unit 10 locking lugs 81 and 82 and 83 and 84, respectively.

At the receiving unit facing end faces, the actuating arms 76 each have a pin or cam-like projection 85 and 86, whose function will be described below.

Furthermore, at the periphery of the cylindrical portion of the dispensing unit 30 is an axial Direction extending, strip-like projection 87 is formed, which engages for rotationally secure fixing of the output unit 30 in the neck region 15 in a corresponding groove 88 on the inner peripheral surface of the neck portion 15.

The locking lugs 81 to 84, which serve as a stop for securing the output unit 30 against unintentional disconnection from the receiving unit 10, are each provided with a bevel at their sides facing away from the chambers 12, 14 of the receiving unit 10, so that the respectively associated transverse web 78 or . 79 of the spring-trained actuator arm 76 and 77 can be driven without much resistance on the respective latching nose 81, 82, 83 and 84.

For the axial positioning of the output unit 30 is the particular in the FIGS. 11 and 12 illustrated adjusting ring 40 used, which is mounted on the front plate 18 of the receiving unit 10 such that the edge regions of the front plate 18 engage in an annular groove 41 of a base plate 42 of the adjusting ring 40. On the base plate 42 of the adjusting ring 40 with respect to the axis of the neck portion 15 offset by 180 ° to each other ramps 43 and 44 are arranged, to each of which a paragraph 45 and 46 connected. The ramps 43 and 44 are each wall-shaped and provided with a substantially arcuate floor plan.

Furthermore, at least at the recesses 45 and 46 facing away from the lowered end portions of the ramps 43 and 44 each adjacent to a groove-like recess 47 and 48, which is arcuate and along the respective ramp 43 and 44 extends.

The adjusting ring 40 cooperates with the actuating arms 76 and 77 of the output unit 30 and thus defines the axial positioning of the output unit 30th

When inserting the dispensing unit in the neck region 15 of the receiving unit 10, the sealing plugs 37 and 38 enter the respective associated outlet openings 11 and 13 of the chambers 12 and 14. The closure plugs 37 and 38 are dimensioned in comparison to the outlet openings 11 and 13 such that the closure plugs 37 and 38 in a first, a closed position representing entry position with their free end portions, the outlet openings 11 and 13 close fluid-tight. Here, the transverse channels 73 and 74 are located on the side facing away from the chambers 12 and 14 of the front panel 18. The entering into the outlet opening 13 end portion of the plug 38 has a four times larger cross-section than the entering into the outlet opening 11 end portion of the sealing plug 37. This is the adjusting ring 40 in a first rotational position, so that the free end faces of the actuating arms 76 and 77 rest on the shoulders 45 and 46 and so a further offset of the output unit 30 in the direction of the chambers 12, 14 is prevented. This position is in Fig. 1 shown. When inserting the dispensing unit 30 in the neck region 15, the transverse webs 78 and 79 cross with elastic spreading or tilting of the actuating arms 76 and 77, the locking lugs 81 and 83, so that they serve between the now serving as a stop or locking latches 81 and 83 on the one hand and on the other hand, also act as a stop, paragraphs 45 and 46. Laterally, the locking lugs 81 and 83 are then guided in each case by a guide track 91 and 92 delimiting wall sections of the actuating arms 76 and 77.

In the first rotational position of the adjusting ring 40, which corresponds to a closed position of the output unit 30, the transverse rods 78 and 79 of the actuating arms 76 and 77 thus cooperate with the detents 81 and 83, whereby the output unit is captively connected to the receiving unit 10.

At the same time, in this blocked state, a further displacement of the dispensing unit 30 in the direction of the receiving unit 10 is limited by the fact that the end faces of the actuating arms 76, 77 abut against the shoulders 45 and 46. Here, a predetermined distance exists between the base plate 36 and the front plate 18, and the closure plugs 37, 38 have just entered the outlet openings 11 and 13 so far that the plugs seal the outlet openings in a fluid-tight manner.

In the closed position of the closure plugs 37 and 38, the chambers 12 and 14 can be filled with substances from their open rear ends. Subsequent to the filling with the substances, the chambers 12 and 14 are closed from the rear with the pistons 21 and 23 of the piston unit 20. This closure position through the closure plugs 37, 38 and through the pistons 21, 23 is in Fig. 1 shown. The filled in the chambers 12 and 14 substances are not shown.

If now the multi-chamber dispenser 100 in the Fig. 2 shown activation state, the adjusting ring 40 is rotated in a second rotational position in which the actuating arms 76 and 77 are each above a Aussparbereiches 49 and 50 of the base plate 42 of the adjusting ring 40. In this rotational position of the adjusting ring 40 is then an axial pressure on the output unit 30 exerted until the actuating arms 76 and 77 abut with their free end faces on the base plate 42 and the projections 85 and 86 of the actuating arms 76 and 77 engage in the recesses 47 and 48 on the base plate 42 of the adjusting ring 40. Thus, a second inlet position of the sealing plug 37 and 38 is made, in which the transverse channels 73 and 74 are disposed within the chambers 12 and 14 and via the transverse channels 73 and 74 and the axial channels 71 and 72, a fluid connection between the chambers 12 and 14 and the Mixing chamber 39 and the output channel 33 of the output unit 30 is made. The inner cross section of the longitudinal channel 72 is four times greater than that of the longitudinal channel 71. The same applies to the transverse channel 74 in comparison to the transverse channel 73rd

When moving the dispensing unit 30 into the activation position, the transverse webs 78 and 79 of the actuating arms 76 and 77 traverse the detents 82 and 84, so that the latter form a stop which secures the dispensing unit 30 in the activation position.

In the activated state of the two-chamber ampule 100, which in Fig. 2 is shown, by exerting pressure on the printing plate 26 of the piston unit 20, the substances contained in the chambers 12 and 14 through the transverse and axial channels 71 to 74 of the closing unit 35 of the dispensing unit 30 into the mixing chamber 39 and the discharge channel 33 and pushed through the tip of the pipe section 32 of the output unit 30 are output. For better mixing of the substances a static mixer is provided in the output channel, which is not shown in detail.

Now, the collar 40 relative to the illustration in Fig. 11 further rotated clockwise, the slide End faces of the actuating arms 76 and 77 on the ramps 43 and 44, so that the output unit 30 in the opposite direction of the chambers 12 and 14 undergoes an axial offset. The projections 85 and 86 rest against the peripheral surfaces of the ramps 43 and 44, so that the actuating arms 76 and 77 are tilted or spread apart in the direction away from the axis of the neck region 15. This allows the transverse webs 78 and 79, the locking projections 81, 82, 83 and 84 traverse. The dispensing unit 30 can thus be unlocked and separated from the receiving unit 10. The region of the ramp 43 or 44 adjoining the shoulders 45 and 46 respectively defines the third rotational position of the adjusting ring 40 which represents an exchange position. The spreading of the actuating arms 76 and 77 in this rotational position of the adjusting ring 40 is in particular Fig. 3 refer to.

The illustrated two-chamber ampule 100 is intended for repeated use. It is therefore applied in an application only a fraction of the substances from the chamber 12 and 14. After completion of an application of the adjusting ring 40 is rotated to the third, the replacement position representing rotational position. In the third rotational position, the dispensing unit 30 can be removed from the neck area 15. Now, after further rotation of the adjusting ring 40 into the first rotational position, a new dispensing unit 30 can be attached to the receiving unit 10.

The replacement of the dispensing unit 30 can be made several times until the chambers 12 and 14 are completely emptied.

In the FIGS. 13 to 17 are an output unit 30 'and a multi-plug closure unit 35' of a second embodiment of a Represent more multi-chamber output device, which incidentally to those of the FIGS. 1 to 12 equivalent.

The output unit 30 'has a cylindrical rear adapter portion 31. The cylindrical adapter portion 31 has an outer diameter such that it from above into the open front end of a neck portion 15 of a corresponding FIGS. 4 to 6 trained recording unit used and is fluid-tightly displaced therein. At a distance from the rear end of the inner surface of the cylindrical adapter portion 31 an obliquely inwardly and forwardly directed peripheral wall 131 is formed. The peripheral wall 131 bounds a rearwardly open, frusto-conical mixing space 39. The narrower front end of the peripheral wall 131 merges into a tubular structure that projects beyond the front end of the adapter section 31 and a pipe section 32 of the output unit 30 '. Within the front tube section 32 extends in the longitudinal direction 30, an output channel 33. The rear end of the discharge channel 36 and the front end of the mixing chamber 39 merge into one another.

At the front end of the cylindrical adapter portion 31, a radially outwardly projecting cross member 75 is formed. At the bottom of the cross member 75 at a distance from the outer circumference of the cylindrical adapter portion 31 rearwardly projecting locking or adjusting arms 76 and 77 are integrally formed.

In particular 15 to 17 it can be seen, the multi-plug closure 35 'has two plugs 37 and 38, which are integrally formed on the underside of a common plate-shaped body 146. The plate-shaped body 146 is adjacent to the plugs 37 and 38 of a Base plate 164, an integrally formed on the upper side of the base plate intermediate plate 162 and an integrally formed on the upper side of the intermediate plate head plate 160, which represents the front end of the multi-plug closure 35 '.

From the top of the top plate 160, two longitudinal channels 71 and 72 extend down to the plugs 37 and 38. The longitudinal channel 71 terminates in a transverse channel 73 passing transversely through the plug 37. The longitudinal channel 72 opens into the plug 38 in the transverse direction Transverse channel 74. The transverse channels 73 and 74 are formed at a predetermined distance from the lower ends of the plugs 37 and 38.

The top plate 160 has a circular peripheral wall having a diameter larger than that of the intermediate plate 162. To make a rotational connection between the dispensing unit 30 'and the multi-plug closure 35', the head plate 160 can be snapped into an annular holding groove 150 from the rear end of the dispensing unit 30 ', which is located below the peripheral wall 131 on the inner surface of the cylindrical adapter portion 31 of the dispensing unit 30'. is trained. The groove 150 and the top plate 160 are matched in terms of their dimensions to one another that the top plate 160 is rotatably supported in the groove 150. Removal of the head plate 160 from the groove 150 is prevented by an annular shoulder 152 formed at the rear end of the inner surface of the adapter portion 31. So that the head plate 160 can be easily snapped into the groove 150 during assembly, the radially inwardly facing surface of the shoulder 152 is chamfered in the manner shown. A longitudinal displacement of the head plate 160 upwards or forwards is limited by a shoulder 154 formed on the underside of the peripheral wall 131.

On the upper side of the head plate 160, a transverse rib 163 is formed, which cooperates with two diametrically opposed recesses 153 in the shoulder 154 such that the multi-plug closure 35 'rotatably supported in the dispensing unit 30' can be releasably locked in a predetermined angular or rotational position ,

The dispensing unit 30 'and the multi-plug closure 35' are thus configured such that these two components form a single structural unit 30 ', 35'.

When inserting the output unit 30 'and multi-plug closure 35' existing unit from the front or from above into the neck region 15 of the container 10, the plugs 37 and 38 enter the outlet openings 11 and 13 of the chambers 12 and 14 a. The plugs 37 and 38 are dimensioned in comparison to the outlet openings 11 and 13 such that the plugs in a first entry position with their rear end portions, the outlet openings 11 and 13 close fluid-tight. In this case, the transverse channels 73 and 74 are located above the front panel 18. The rear portion of the plug 38 entering the outlet opening 13 has a cross section four times greater than the rear portion of the plug 38 entering the outlet opening 11.

In a further downwardly or rearwardly displaced second inlet position of the plugs 37 and 38, the transverse channels 73 and 74 are below the front plate 18, so that via the transverse channels 73 and 74 and the longitudinal channels 71 and 72, a fluid connection between the interior the chambers 12 and 14 and the mixing chamber 39 and the output channel 32 of the output unit 30 'consists. The inner cross section of the longitudinal channel 72 is four times greater than that of the longitudinal channel 71. The same applies to the transverse channel 74 in comparison to the transverse channel 73rd

For better guidance of the multi-plug closure 35 'in the neck region 15, the base plate 164 has a circumferential wall which is adapted at least over partial regions of the circumference of the inner peripheral wall of the neck region 15. In such a portion of the peripheral wall of the base plate 164, a radially projecting lug 161 is formed. The projection 161 cooperates in the initial insertion of the multi-plug closure 35 'in the neck region 15 with a formed in the inner surface of the neck portion 15 longitudinal groove such that the Mehrstopfenverschluss 35' can be used only in a predetermined angular or rotational position in the neck region 15, in the plugs 37 and 38 are aligned with the outlet openings 11 and 13 of the chambers 12 and 14.

Incidentally, the structure and operation of the second embodiment correspond to the structure and operation of the embodiment according to the FIGS. 1 to 12 That is, it is also a collar provided which defines the axial positioning of the output unit 30 'and multi-plug closure 35' formed unit.

Claims (26)

1. Multi-chamber dispenser for the dispensing of a mixture made of several substances, equipped with:

   - a unit of measurement (10) with several chambers (12, 14) with a parallel alignment one to another wherein each of them has an open first ending for the insertion of a flask (21, 23) and a second ending equipped with an exit opening (11, 13) and with a neck area (15) with an alignment in the upstream area to the exit opening (11, 13) of the chambers (12, 14) and

   - an output unit (30, 30') equipped with an output channel (33) and an adapter section for the impermeable connection with the neck area (15) of the unit of measurement (10),

   - an adjusting collar (40) for the axial positioning of the output unit (30, 30') which is pivoted on the unit of measurement (30) and encompasses the unit of measurement (20), characterized in that the adjusting collar (40) is equipped with at least one ramp (43, 44) interacting at least with one adjusting arm (76, 77) supported by the adjusting collar (40) so that the output unit (30, 30') is axially displaced in case of a rotation of the adjusting collar (40).
2. Multi-chamber dispenser according to claim 1, characterized in that the adjusting collar (40) has at least a first rotation position defining a rest position in which a substance flow between the chambers (12, 14) and the outlet channel (33) of the output unit (30, 30') is locked by the output unit (30, 30'), and a second rotation position defining an outlet position in which the substances from the chambers (12, 14) can be transferred into the outlet channel (33) being applicable through it.
3. Multi-chamber dispenser according to claim 2, characterized in that the adjusting collar (40) engages in the rest position and in the outlet position into an engaging device.
4. Multi-chamber dispenser according to one of the claims 1 to 3, characterized in that the adjusting collar (40) is mounted on a front plate (18) extending transversally to the longitudinal axle of the chambers (12, 14) which is molded in the area of the second ending of the chambers (12, 14) of the unit of measurement (10).
5. Multi-chamber dispenser according to claim 1, characterized in that the ending area of the ramp (43, 44) turned away from the chambers (12, 14) defines a third rotation position of the adjusting collar (40) in which the output unit (39, 30') can be removed from the neck area (15) of the unit of measurement (10).
6. Multi-chamber dispenser according to claim 1 or 5, characterized in that the output unit (10) is ejected from the neck area (15) by the ramp (43, 44) after the rotation of the adjusting collar (40).
7. Multi-chamber dispenser according to claim 1, characterized in that the ramp (44, 45) is extended over an angular range between 90° and 160°.
8. Multi-chamber dispenser according to one of the claims 1 to 7, characterize in that the adjusting collar (40) is equipped with a radial groove (41) in which the external border area of the front plate (18) engages.
9. Multi-chamber dispenser according to one of the claims 1 to 8, characterized in that the output unit (30) is mounted in a rotatably fixed manner into the neck area (15).
10. Multi-chamber dispenser according to claim 9, characterized in that the neck area (15) has an elliptical-shaped cross-section.
11. Multi-chamber dispenser according to claim 9 or 10, characterized in that in the neck area (15) a rotary protection (87) is aligned for the output unit (30).
12. Multi-chamber dispenser according to one of the claims 1 to 11, characterized in that the adjusting arm (76, 77) supported by the adjusting collar (40) is designed on the output unit (30, 30').
13. Multi-chamber dispenser according to claim 12, characterized in that the output unit (30, 30') comprises a cross bar (75) from which the adjusting arm (76, 77) sticks out towards the direction of the chambers (12, 14) of the output unit (10).
14. Multi-chamber dispenser according to claim 12 or 13, characterized in that the adjusting arm (76, 77) is elastically pre-stressed towards the direction of the axle of the neck area (15).
15. Multi-chamber dispenser according to claim 1 and according to the claims 12 to 14, characterized in that the adjusting arm (76, 77) in the first rotating position of the adjusting collar (40) bears on an offset(45, 46) of the adjusting collar (40).
16. Multi-chamber dispenser according to claim 1 and according to the claims 12 to 15, characterized in that the ramp (43, 44) interacts with the adjusting arm (76, 77) so that the adjusting arm (76, 77) by the rotation of the adjusting collar (40) tilts towards the direction turned away from the axle of the neck area (15) and so that the output unit (30, 30') is unlocked.
17. Multi-chamber dispenser according to one of the claims 1 to 16, characterized in that on the external wall of the neck area (15) at least one engaging mean (81, 82, 83, 84) is aligned for the adjusting arm (76, 77) which preferably interacts with a cross web (78, 79) of the adjusting arm (76, 77).
18. Multi-chamber dispenser according to claim 17, characterized in that the engaging mean (81, 82, 83, 84) locks the output unit (30) in the rest position and/or in the output position.
19. Multi-chamber dispenser according to the claims 17 or 18, characterized in that the engaging mean (81, 82, 83, 84) is equipped with a chamfer on the side turned away from the chambers (12, 13) of the unit of measurement (10).
20. Multi-chamber dispenser according to one of the claims 1 to 19, characterized in that the output unit (30, 30') is equipped with a locking unit (35, 35') for the exit openings (11, 13) of the chambers (12, 14) of the unit of measurement (10).
21. Multi-chamber dispenser according to claim 20, characterized in that the locking unit (35, 35') for each chamber (12, 14) comprises a closing plug (37, 38) attributed to the respective exit opening (11, 13).
22. Multi-chamber dispenser according to claim 21, characterized in that the closing plugs (37, 38) in their output position respectively enable one substance flow to a mixing chamber (39) which is aligned in the output unit (30, 30') upstream on the output channel (33).
23. Multi-chamber dispenser according to claim 22, characterized in that the closing plugs (37, 38) are respectively equipped with one cross channel (73, 74) connected with a blind hole-shaped axial channel (71, 72) leading to the mixing chamber.
24. Multi-chamber dispenser according to one of the claims 20 to 22, characterized in that the locking unit (35') has a platform-shaped body (146) which is rotatably mounted on the side turned to the unit of measurement (30') of the output unit (30, 30').
25. Multi-chamber dispenser according to claim 24, characterized in that on the output unit (30') and the platform-shaped body (146) of the locking unit (35') there are engaging means (153, 163) interacting so that the output unit (30') and the locking unit (35') can be snapped into place in a preset position of the rotation angle.
26. Multi-chamber dispenser according to claim 25, characterized in that on the platform-shaped body (146) of the locking unit (35') an offset (161) overhanging towards the transverse direction is formed and interacts with a longitudinal groove designed in the internal part of the neck area (15) so that the locking unit can be introduced into the neck area (15) only in a preset rotation angle position in which the closing plugs (37, 38) of the locking unit (35') are aligned with the respective exit openings (11, 13) of the chambers (12, 14).

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