EP2669200A1 - Container closing apparatus with integrated head space flushing - Google Patents

Abstract

The device has a conveyor star for conveying containers (2). A closing element closes the conveyed container. A nozzle carrier (4) includes upwardly oriented nozzles (40) for injecting flush gas into closures (3), and downwardly oriented nozzles (42) for injecting the flush gas into a head chamber volume (24) of the containers. The nozzle carrier is arranged outside a sphere of the closing element. The nozzle carrier lies outside or within a pitch circle. Two sterilized filtering candles are provided before the nozzle carrier.

Description

Technical area

The present invention relates to a device for closing containers with closures, preferably for closing containers with plastic screw caps, roll-on closures or bottle caps.

State of the art

When closing containers with closures, it is known, in particular during the filling of oxygen-sensitive beverages, to rinse the head space volume of the respective container with an inert gas or with nitrogen in order to displace the oxygen from the head space of the container.

For metering nitrogen, it is known, for example, to introduce a drop of liquid nitrogen through the mouth of the container, the liquid nitrogen then evaporating in the headspace of the container and correspondingly displacing the oxygen contained therein. Corresponding metering devices include a nitrogen nozzle mounted on the pitch circle above the mouths of the respective containers so that a drop of liquid nitrogen can be metered through the mouth into the head space. Accordingly, the nozzle is arranged directly above the mouth, so that closing the container with a closure at the same time for metering in the nitrogen plug is impossible. However, simultaneous capping with the metering in of the nitrogen plug is also undesirable in the use of liquid nitrogen because the nitrogen must first evaporate to displace the oxygen before the respective plug is applied. Accordingly, part of the treatment angle is used here to await the evaporation of the nitrogen droplet. A corresponding system is for example from the EP 1 651 555 B1 known.

Another system is known in which gaseous nitrogen is injected via a first side-mounted nozzle in the headspace of the container and via a disposed on the opposite side of the second nitrogen nozzle, gaseous nitrogen is injected into the closure. In this way, a displacement of the oxygen is achieved both in the headspace of the container and in the closure. A corresponding system is for example from the WO 2010/087097 A1 known.

Another device for gassing both the headspace and the closure is from the JP 2004-161350 A Here, a single, arranged between the closure and the headspace of the container nozzle carrier is provided, which each comprises upwardly directed nozzles for rinsing the closure and downwardly directed nozzles for rinsing the headspace.

Presentation of the invention

Starting from the known state of the art, it is an object of the present invention to further optimize the capping action and the displacement of oxygen from the headspace volume.

This object is achieved by the device for closing containers with closures with the features of claim 1. Advantageous developments emerge from the subclaims.

Accordingly, the device for closing containers with closures comprises a conveyor star for conveying the container and at least one closing element for closing the container conveyed with the conveyor star. It further comprises a nozzle carrier with upwardly directed nozzles for blowing purge gas into the closure and with downwardly directed nozzles for injecting purge gas into the head space of the container. According to the invention, the nozzle carrier is arranged outside the effective range of the closing element.

Due to the fact that the nozzle carrier is arranged outside the effective range of the closing element, a gassing can take place during the entire closing operation and the lowering movement of the closing element can be started at an early stage. In particular, the gassing process can be started when the headspace of the Container and the closure are still freely accessible, so that the nitrogen gas can be injected obliquely from below into the closure, which is already in the closing element, and from obliquely upwards into the headspace of the container guided in the guide star. Due to the arrangement of the nozzle carrier with the nozzles outside the effective range of the closing element, the gas flow, which is applied via the nozzles of the nozzle carrier, can be maintained correspondingly, until the closure is completely seated on the container.

Accordingly, a reliable flushing of both the headspace volume and the inner volume of the closure takes place, so that here an oxygen-poor to oxygen-free atmosphere can be produced, which has a particularly advantageous effect on the shelf life of the corresponding bottled drinks. In other words, the gas flow with the oxygen-free gas can be maintained by the lateral arrangement of the nozzle carrier outside the effective range of the closing element during the complete closing operation. Accordingly, the residual oxygen content in the headspace after putting on the closure or after the conclusion of the closing process is particularly low.

The nozzle carrier is preferably outside the pitch circle in such a way that it is possible to inject the nitrogen into the headspace and closure. In an alternative, the nozzle carrier can be correspondingly also mounted within the pitch circle so that a corresponding injection of nitrogen is made possible.

The nozzle carrier preferably extends over an angular section along the pitch circle, which can be extended between the position of the picking of the respective closure up to a position of complete placement or complete closure of the closure. Particularly preferably, the nozzle carrier extends over this angular range. By means of a correspondingly long action section of the gas, an effective displacement of the oxygen from the head space and closure up to the complete closure of the container with the closure can be achieved accordingly. At the same time, due to the long exposure time of the gas flow, the injection pressure or the injection velocity of the gas can also be reduced.

The nozzle carrier preferably has a multiplicity of gas nozzles which are directed upwards in order to inject gas into the closure. Furthermore, a plurality of gas nozzles are preferably provided, which are directed downward to allow injection of the gas into the headspace of the container.

In a particularly preferred variant, the nozzles are arranged along the nozzle carrier at different angles in order to allow the most accurate possible injection into the closure and the head space of the container. In a screw capper for screwing plastic caps on bottles, the container is usually performed on a neck ring at a constant height, whereas the closing element is lowered with the screw cap received therein to the mouth of the container. Accordingly, the gas nozzles are preferably arranged such that the lower gas nozzles, which aim into the head space of the container, are arranged at always the same angle on the nozzle carrier, but the upper nozzles, which aim into the closure, are arranged at different angles, that the gas flow follows the lowering movement of the closure. Thus, the upwardly directed nozzles at the beginning of the gassing are directed upwards steeper than to the end of the gassing out.

In a preferred embodiment, additional upwardly directed Umspülungsdüsen above the upwardly directed nozzles and / or additional downwardly directed Umspülungsdüsen below the downwardly directed nozzles and / or additional Umspülungsdüsen between the upwardly directed nozzles and the downwardly directed nozzles are provided. By means of the additional circulation nozzles, a type of purge gas curtain can be provided around the area of the closure and the mouth of the container to be closed. Thus, even with the movement of the closure relative to the orifice during the actual closing of the container, a substantial to complete shielding with the purge gas, preferably an inert gas, can be achieved. The intake of ambient air into the container when closing the container by the turbulence occurring can be reduced or even avoided and, accordingly, the shelf life of the bottled beverages can be further improved.

Preferably, the additional circulation nozzles are arranged only in a section of the nozzle carrier with respect to its angular extent. The risk of contamination of the containers by the intake of ambient air into the container is the end of the lowering process highest, since the ambient air can then no longer be removed by subsequent flushing with purge gas from the container. An arrangement of the additional rinsing nozzles in the angular range of the nozzle carrier, which corresponds to the completion of the lowering operation of the closure on the mouth of the container, is therefore preferred. In this way, purge gas can be saved at the beginning of the lowering process.

Particularly preferably, the additional rinsing nozzles are designed so that the purge gas exiting therefrom has a lower flow than that of the upwardly directed nozzles and / or the downwardly directed nozzles. This lower flow is preferably achieved by selecting a corresponding diameter of the additional circulation nozzles. Due to the lower flow or a lower pulse of the exiting gas, the ambient atmosphere is washed away by a very gentle purge gas flow, but without destroying the purge gas atmosphere.

In this context, the additional circulation nozzles can be fed via a separate from the upwardly directed nozzles and the downwardly directed nozzles purge gas, which is preferably acted upon by a lower purge gas pressure. At this separate purge gas supply can advantageously be connected to another purge gas source, which supplies a different pressure, or which supplies another purge gas or inert gas. The separate purge gas can also be connected via a pressure reducing valve to the first purge gas source.

By means of the additional circulation nozzles, the respective cleaning area can be widened even during a cleaning process, and the cleaning liquid can be specifically applied to specific areas of the installation or to the surfaces of the installation. For example, the upwardly directed nozzles may splash into the capping head and inject the additional upwardly directed dishwashing nozzles from the outside onto the capping head.

By arranging the nozzle carrier with the nozzles outside the effective range of the closing element, it is furthermore possible to lower the closing element earlier than would be possible with an arrangement of a nitrogen nozzle between the closure and the container. Correspondingly, an angle section of the pitch circle for purging the head space and the closure can also be reduced or reduced so that the performance of the capper can be increased.

Furthermore, can be reduced by the long exposure period of the gas flow as well as arranged opposite the container and closure nozzles significantly flatter injection of nitrogen pressure or the flow velocity of the purge gas, so that squirting of product from the respective containers by the injected gas avoided in this way can be.

In a particularly preferred variant, the nozzle carrier has a valve for introducing a cleaning liquid, for example cleaning foam or hot liquor. In this way, the nozzle carrier with the nozzles attached thereto can be completely cleaned and can also, with appropriate pressure control, also be used to pressurize the conveyor star through the nozzles of the nozzle carrier with detergent and in particular to pressurize the closing element from below with the cleaning liquid , In this way, an effective cleaning of both the nozzle carrier with the nozzles and the overall device is achieved.

Brief description of the figures

Figur 1

den Düsenträger, ein Verschluss, sowie einen Behälter in einer schematischen Schnittdarstellung;

Figur 2

eine Vorrichtung zum Verschließen von Behältern in einer schematischen perspektivischen Darstellung;

Figur 3

eine Vorrichtung zum Verschließen von Behältern in einer schematischen Draufsicht; und

Figur 4

eine schematische verfahrenstechnische Anbindung.

Preferred further embodiments and aspects of the present invention are explained in more detail by the following description of the figures. Showing:

FIG. 1

the nozzle carrier, a closure, and a container in a schematic sectional view;

FIG. 2

a device for closing containers in a schematic perspective view;

FIG. 3

a device for closing containers in a schematic plan view; and

FIG. 4

a schematic procedural connection.

Detailed description of preferred embodiments

In the following, preferred embodiments will be described with reference to the figures. In this case, identical, similar or equivalent elements in the different figures are denoted by identical reference numerals and a repeated description of these elements will be omitted in the following description in part in order to avoid redundancies.

In FIG. 1 schematically a cross-section through a portion of the device for closing containers 2 with a closure 3 is shown. The container 2 has an opening 20 to which the closure 3 is to be screwed. For this purpose, the closure 3 preferably has an internal thread 30, which is screwed to a corresponding external thread in the region of the mouth 20 of the container 2.

In the area between the mouth 20 and the liquid surface 22 of the filled product in the container 2, a head space 24 is provided, which is initially filled with ambient air from the filling plant. The closure 3 has in its interior an internal volume 32, which is originally also filled with ambient air.

A nozzle carrier 4 with an upwardly flowing nozzle 40 for flowing in a guided in the nozzle carrier 4, or in a cavity 44 of the nozzle carrier 4, gas is provided. The upwardly directed nozzle 40 is aligned so that the gas stream is flowed into the interior 32 of the closure 3.

Furthermore, a downwardly directed nozzle 42 is provided, which is oriented so that the gas flow leaving it flows into the head space 24 of the container 2.

The nozzle carrier 4 is arranged in its height so that the nozzles 40, 42 at the beginning of the rinsing preferably at about the same distance from the respective inlet openings, ie the mouth 20 and the opening of the shutter 3, have. During the closing process, the closure 3 is lowered onto the mouth 20 of the container 2, so that here the distances to the nozzle carrier 4 change.

Out FIG. 1 is further seen that the nozzle carrier 4 is formed in a ring portion having a radius such that the nozzle carrier 4 is outside the mouth 20 and outside of the closure 3. In other words, the closure 3 can be lowered to the mouth 20 without the nozzle carrier 4 being in the way.

Among others, the in FIG. 1 shown rhombic shape of the nozzle carrier 4, which has a corresponding taper in the upper region. This taper can be designed to be complementary to the outer dimensions of a closing element. Accordingly, even when the closure 3 is fully seated on the mouth 20 of the container 2, the nozzle carrier 4 can still be provided and correspondingly continue to provide a purge gas flow.

The nozzle carrier 4 is arranged so that it also outside the sphere of action of an in FIG. 1 Closing element, not shown, for closing the container 2 with the closure 3 is formed. This arrangement results, for example FIG. 2 according to which the individual closing elements 6 can be lowered completely onto the respective containers 2 in order to apply the closures 3, but without colliding with the nozzle carrier 4.

As purge gas which is supplied through the inner space 44 of the nozzle carrier 4 to the nozzles 40, 42, preferably nitrogen - that is N ₂ - used. Other suitable gases, in particular inert gases, but can also be used for rinsing.

In FIG. 1 two additional circulation nozzles 41 and 43 are shown, which are arranged on the nozzle carrier 4. The additional rinse nozzle 41 is above the upwardly directed nozzle 40, and the additional rinse nozzle 43 is disposed below the downwardly directed nozzle 42. The additional circulation nozzles 41, 43 serve to form a kind of purge gas curtain around the closure 3 and the mouth 20 around, in order to reduce the intake of ambient air into the container 2 or even in turbulence resulting from the relative movement between the closure 3 and the mouth 20 during the closing process to avoid.

The additional flow-around nozzles 41, 43 can be adapted in their diameter so that a very gentle purging gas flow, the ambient atmosphere from the closure region rinses. The are in the FIG. 1 shown additional Umspülungsdüsen 41, 43 connected to the spülgasführenden cavity 44 of the nozzle carrier 4.

Alternatively, however, it is possible in a variant, not shown, to provide a further channel for the supply of the circulating gas in the nozzle carrier 4. At this channel, for example, another purge gas source can then be connected to another purge gas and / or another pressure. In a further alternative, the further channel can also be connected via a pressure reducing valve to the first purge gas source, so that only a different pressure for the purge gas is provided here. In this way, the purge gas exiting the additional purge nozzles 41, 43 may have a lower flow velocity and thus a lower pulse, so that the purge gas atmosphere thus formed will not be blown around the occlusion region.

The additional circulation nozzles 41, 43 furthermore have the advantage that cleaning agents can be applied to them in a targeted manner through them. For example, the upwardly directed nozzles 40 inject into the closing element 6, and the additional flow nozzle 41 sprays from the outside onto the closing element 6. This allows the desired cleaning effect or the desired cleaning range to be determined in a targeted manner.

The additional circulation nozzles 41, 43 may preferably be arranged only in a section of the nozzle carrier 4 with respect to its angular extent. The risk of loading the container 2 by drawing ambient air into the container 2 is the highest at the conclusion of the lowering process, since the ambient air can not be removed from the container 2 by subsequent flushing with flushing gas. An arrangement of the additional circulation nozzles 41, 43 in the angular region of the nozzle carrier 4, which corresponds to the completion of the lowering operation of the closure 3 on the mouth 20 of the container 2, is therefore preferred. In this way, purge gas can be saved at the beginning of the lowering process.

In FIG. 2 For example, an exemplary apparatus 1 for closing containers is shown in a schematic perspective view, wherein no containers are shown here. The containers are usually conveyed by means of the schematically indicated conveyor star 5. In the conveyor star 5 the in FIG. 2 In the embodiment shown, the containers are held at their respective neck rings and guided in a circle by means of the conveying star 5. On the respective receiving pockets for the mouths of the container in the conveyor star 5 closing elements 6 are provided, by means of which closures, such as in FIG. 1 shown closure 3, can be applied to the mouths 20 of the container.

For this purpose, the respective closures are transferred via a pick wheel 60 on the pitch circle of Verschließelemente 6, removed at the tangential transfer point by a downward movement of the Verschließelementes 6 from the pick wheel 60, and then subsequently lowered to an orifice of a container and connected thereto.

In the embodiment shown, the closing element 6 is intended to screw a plastic screw cap onto a PET bottle. However, other closing elements 6 are also conceivable in this configuration, such as, for example, closing elements for rolling on roll-on closures or for applying crown corks.

In an angular portion of the pitch circle of the nozzle carrier 4 is provided, wherein the corresponding angular portion of the pitch circle is selected so that the gas stream can be injected into the head space volume of the container to be closed and the closure, which is already in the closing element 6, also with the gas flow can be applied. Accordingly, ambient air or oxygen is displaced both from the head space and from the volume defined by the closure by the inflowing N ₂ gas.

Due to the arrangement of the nozzle carrier 4 such that it lies outside the effective range of the closing element 6, the closing operation of the container can take place, although a gas flow is provided by means of the nozzles 40, 42 arranged in the nozzle carrier 4 and the circulating nozzles 41, 43. In other words, the closing element 6 can perform the necessary for the closing stroke movement in the presence of the nozzle carrier 4 completely. Accordingly, the entire closing operation, be accompanied by the gas purging, at least until the complete placement of the closure on the mouth of the container. This ensures that the residual oxygen in the headspace volume of the then sealed container is very low.

In the in FIG. 2 In one embodiment, it is preferable for the nozzle carrier 4 to be provided with nozzles pointing downwards for injecting the gas stream into the nozzle Equip the headspace of the container that here a constant current, preferably at a constant angle takes place.

Since the closure 3 is lowered together with the closing element 6 so that the closure 3 can be screwed onto the container, the orientation of the nozzles pointing upwards in the nozzle carrier 4 preferably varies so that an optimal injection of the respective gas stream into the through the closure defined volume takes place.

Correspondingly, the nozzles arranged in the nozzle carrier 4 and pointing upwards can be oriented differently over the length of the nozzle carrier 4. Furthermore, the cross section of the nozzle carrier 4 can change over its length, whereby, for example, the flow emerging from the respective nozzles can be kept essentially the same over the entire length of the nozzle carrier.

Even if in FIG. 2 a preferred variant is shown to the effect that the nozzle carrier 4 outside the pitch circle on which the mouths of the container and the closing elements 6 are guided, can be arranged in a variant of the nozzle carrier 4 on the inside, ie within the pitch circle ,

In FIG. 3 is a schematic plan view of the device 1 for closing containers shown, wherein the individual closing elements 6 can be seen. About an inlet star 70 and an outlet star 72 to be closed containers are supplied. The closures can be transferred to the closing elements 6 via the picking wheel 60.

In turn, schematically shown is the nozzle carrier 4, which is provided with the corresponding, downwardly and upwardly radiating nozzles 40, 42 for introducing the purge gas into the headspace volume of a container as well as into the volume defined by a closure. As it turned out FIG. 3 results, the nozzle carrier 4 extends over a relatively wide angular portion of the pitch circle, so that a blowing of the purge gas, preferably N ₂ , both in the head space and in the volume formed by the closure is possible until the closure completely on the mouth of Container is placed. In this way it can be achieved that hardly any oxygen enters the closure or the headspace volume even after the rinsing process.

In FIG. 3 is further indicated on the nozzle carrier 4 schematically a valve 8, which allows the integration into the cleaning circuit of the device 1 (so-called cleaning-in-place) for rinsing the nozzle carrier 4 with hot liquor, with foam or other cleaning fluid. Accordingly, the nozzle carrier 4 can be cleaned from the inside and all nozzles 40, 42 and wash-around nozzles 41, 43 can be flushed with the cleaning liquid. Due to the simple geometric shape, such as in FIG. 1 is shown, the nozzle carrier 4 can also be easily rinsed or cleaned from the outside, in particular also because no horizontal surfaces are provided, on which the cleaning liquid could accumulate.

Furthermore, when the nozzle carrier 4 is acted upon by the cleaning medium, the conveying star 5 and the undersides of the closing elements 6 can also be rinsed. According to the construction shown, in addition to the advantageous handling in the displacement of oxygen from the headspace volume, at the same time an improved behavior during cleaning.

FIG. 4 schematically shows a circuit diagram for supplying the purge gas to the individual purge valves 40, 42. In particular, the purge gas is introduced at the gas inlet 90, for example N ₂ with an overpressure of 6 to 8 bar. By means of various measuring devices and a pressure reducer 92, the gas is then transferred via two sterilized filter cartridges 94 to the corresponding nozzles 40, 42. The sterilization of the gas to be injected in the filter cartridges 94 counteracts the entry of germs into the container to be closed.

Via a sterilization steam connection 96, superheated steam for sterilizing both the filter cartridges 94 and the nozzles 40, 42 or the nozzle carrier can be introduced into the system. The corresponding superheated steam is present, for example, at a pressure of 3 bar and can be applied via corresponding feed lines 980 into the filter cartridges 94 or via a feed line 982 directly to the nozzles 40, 42 or the nozzle carrier 4.

If additional circulation nozzles 41, 43 are arranged in the nozzle carrier 4, then they are also subjected to flushing gas and sterilization medium accordingly.

A supply line 984 for scouring liquor in the nozzle carrier 4 or in the cavity 44 is also shown. The feed line 984 is equipped with a CIP system (cleaning-in-place system) connected, so that the cleaning process can be integrated into the cleaning circuit of the device 1.

The filter cartridges 94 are designed so that the N _{2 is} sterile filtered, so that it can be used for application in an aseptic system for the aseptic filling of beverages.

Accordingly, by the described device for closing containers a gassing of the head space and the closure can be achieved until the closure is completely placed on the container to be closed, so that the re-entry of atmospheric oxygen is greatly reduced or completely prevented. The resulting low-oxygen atmosphere in the headspace of the container counteracts the oxidation of oxygen-sensitive products.

Furthermore, by applying the nitrogen under reduced pressure, it is possible to substantially prevent the product from being splashed out when the nitrogen is injected, which is also assisted by the relatively shallow injection of nitrogen.

Furthermore, a simple and reliable sanitation can be achieved by the corresponding geometry of the nozzle carrier 4 and the possibility of easy flow through the nozzle carrier 4, the nozzles 40, 42 and the Umspülungsdüsen 41, 43 with sterile steam, hot liquor, foam or other sanitation.

As far as applicable, all the individual features illustrated in the individual embodiments can be combined and / or exchanged without departing from the scope of the invention. <U> REFERENCE LIST </ u> 1 contraption 2 container 20 muzzle 22 liquid surface 24 Headspace volume 3 shutter 30 inner thread 32 Inner volume of the closure 4 nozzle carrier 40 upward flowing nozzle 41 additional upflowing flushing nozzle 42 down flowing nozzle 43 additional downwardly flowing wash-up nozzle 44 Cavity of the nozzle carrier 5 star conveyor 6 closing 60 Pickrad 70 feed star 72 outlet star 8th Valve for rinsing eye 90 gas inlet 92 pressure reducer 94 sterile filter candle 96 Sterilization Steam connection 980 feed 982 feed 984 Supply line for rinse liquor

Claims (13)

Device (1) for closing containers (2) with closures (3), comprising a conveying star (5) for conveying the containers (2) and at least one closing element (6) for closing the containers (2) conveyed with the conveying star (5) ), further comprising a nozzle carrier (4) with upwardly directed nozzles (40) for injecting purge gas into the closure (3) and with downwardly directed nozzles (42) for injecting purge gas into the head space (24) of the container (2 )
characterized in that
the nozzle carrier (4) is arranged outside the effective range of the closing element (6). Device (1) according to claim 1, characterized in that the nozzle carrier (4) lies outside the pitch circle. Device (1) according to claim 1, characterized in that the nozzle carrier (4) lies within the pitch circle. Device (1) according to one of the preceding claims, characterized in that the nozzle carrier (4) in an angular range between the position of a picking station (60) and the position at which the container (2) is completely closed, is arranged. Device (1) according to claim 4, characterized in that the nozzle carrier (4) extends over the angular range. Device (1) according to one of the preceding claims, characterized in that at least two of the upwardly directed nozzles (40) have different gas outlet angles with respect to the nozzle carrier (4). Device (1) according to one of the preceding claims, characterized in that additional rinsing nozzles (41) are arranged above the upwardly directed nozzles (40). and / or additional rinse nozzles (43) are provided below the downwardly directed nozzles (42) and / or additional rinse nozzles are provided between the upwardly directed nozzles (40) and the downwardly directed nozzles (42). Device (1) according to claim 7, characterized in that the additional circulation nozzles (41, 43) are arranged only in a portion of the nozzle carrier (4) with respect to the angular extent thereof. Device (1) according to claim 7 or 8, characterized in that the additional circulation nozzles (41, 43) are formed so that the purge gas leaving them has a lower flow than that of the upwardly directed nozzles (40) and the downwardly directed nozzles (42) exiting purge gas, preferably by selecting a corresponding diameter of the additional Umspülungsdüsen (41, 43). Device (1) according to one of Claims 7 to 9, characterized in that the additional circulation nozzles (41, 43) have a purge gas feed which is separate from the upwardly directed nozzles (40) and the downwardly directed nozzles (42) and which preferably has another purge gas pressure can be acted upon. Device (1) according to one of the preceding claims, characterized in that the nozzle carrier (4) has a substantially rhombic cross-section. Device (1) according to one of the preceding claims, characterized in that in front of the nozzle carrier (4) is provided a gas sterilizing device (94) which serves to sterilize the gas discharged from the nozzles (40, 42). Device (1) according to one of the preceding claims, characterized in that a valve (8) for introducing a cleaning medium into the nozzle carrier (4) is provided.

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