EP4204342A1 - Transport device for transporting containers - Google Patents

Abstract

The invention relates to a transport device for transporting containers (2) along a container transport path (S), comprising at least one transport star (1). The transport star (1) has at least one first rotor-like transport element (3) which is oriented on a first horizontal plane and can be rotated about a first vertical star axis (SA1), and a plurality of first container supports (4), each of which is arranged at a first vertical position (h1) and which engage the containers (2) at a first gripping height, are distributed over the circumference of the first transport element (3) about the first star axis (SA1) in order to hold the containers (2) in a suspended manner. At least one first motor drive (7) is provided in order to rotate at least the first rotor-like transport element (3). The invention is characterized in particular in that the transport star (1) additionally has a second rotor-like transport element (5) which is designed to have the same circumference as the first transport element (3), is oriented on a second horizontal plane, and can be rotated about a second vertical star axis (SA2), and a number of container supports (6), each of which is arranged at a second vertical position (h2) and which engage the containers (2) at a second gripping height, are distributed over the circumference of the second transport element (5) in order to hold the containers (2) in a suspended manner. The first and second star axis (SA1, SA2) are offset to each other, and the transport elements (3, 5) partly overlap.

Description

Transport device for transporting containers

The invention relates to a transport device for transporting containers and to a container transport section with such a transport device and to a method for transporting containers.

Transport devices for transporting containers are well known. In this case, empty or filled containers are conveyed or transported along a transport or conveyor route, for example on predetermined transport routes between successive container treatment machines, container treatment stations or units in a production process, in particular from a treatment machine to a container treatment machine of a container treatment plant that follows in a transport direction.

In the beverage industry in particular, the containers, for example bottles, are not only transported in an upright position, for example by means of so-called belt or chain conveyors, but also in particular off the ground, i.e. hanging, for example via star conveyors or transport stars. This hanging transport of bottles is also generally referred to as "neck handling".

Such corresponding star conveyors or transport stars or transporters are usually designed in the form of a star-wheel-like rotor or transport wheel that can be driven to revolve around a vertical machine axis and have a large number of container receptacles or container carriers on the circumference, for example in the form of grippers, clamps, etc , namely for the hanging mounting of the containers, in particular the containers designed as bottles, preferably PET bottles. As a rule, a flange is formed or formed on the containers to be transported in the region of the bottle neck, namely in the neck region of the container, which flange is usually also referred to as a neck ring. The container receptacles or container carriers can be designed and arranged in such a way that they hold the containers below the flange or above the flange to grab. In technical jargon, this is often also referred to as "underneck" gripping or "overneck" gripping.

It is also known to connect several corresponding transport wheels or star conveyors or star conveyors to one another in a container transport direction, i.e. to connect them to form a container transport section, the containers being transferred on their movement path from a respective transport wheel arranged upstream in the container transport direction to a respective downstream transport wheel, in particular at transfer positions where adjacent transport wheels abut each other. Adjacent transport wheels rotate in opposite directions, that is, in opposite directions of rotation. The star wheel-like transport wheels, which can be driven continuously, can also have different diameters.

For an effective container transfer from one transport wheel or star wheel to the next, but also for the transfer from one transport wheel to a rotating container treatment station or machine, depending on the design of the container receptacles or container carriers, adjacent transport wheels can mesh with one another or the transfer can take place, for example, by The containers are pushed over by means of deflection elements provided. Transport stars with active, controlled clamps are also known, which can switch between a gripping position and a release position by means of a correspondingly controlled opening and closing movement. There are also solutions in the prior art that provide active, controlled transfer clamps for transferring the containers from a transport wheel to a continuously rotating container treatment machine, as described, for example, in WO 2017/174772 A1.

In the beverages industry in particular, efforts have been made for some time to implement the container treatment systems in ever more compact and blocked configurations of the individual container treatment machines. In particular, the trend in recent years to manufacture the PET containers directly in the container treatment plant designed for filling by stretch blow molding, and in doing so to constantly reduce the container weights of the PET containers, has had an impact on the so-called line design of the container treatment plants. Recently, all machines and transport routes have been blocked directly preferred, whether for example as a blow-fill block or even as a blow-label-fill block. In these blocks, the containers are transported, for example, on a predetermined movement path starting from the blow molding machine via several transport wheels connected in series to the labeling machine and/or to the filler.

In order to make the transfer of the containers between the transport wheels quick, efficient and as trouble-free as possible, the transport wheels of a transport route are often arranged in such a way that one transport wheel with a gripping position below the neck ring and one transport wheel with a gripping position above the neck ring are arranged alternately , so that when the containers are transferred between consecutive transport wheels, there is a change from "under the neck" gripping to "over the neck" gripping - and vice versa. For example, it is known from publication WO 2014/026732 A1 to arrange the clamps of transport stars arranged one behind the other on different horizontal planes, so that the transport wheels can “mesh” in relation to their clamps and thus the containers can be transferred between adjacent transport stars.

With all the solutions known from the prior art, however, continuous neck handling cannot be achieved at all, or at most with considerable technical and design effort, in systems that are increasingly compressed, blocked and compact in the smallest possible space.

The object of the invention is to provide a transport device for transporting containers along a container transport route which, with a technically, structurally simple and space-saving design, improves the transport of containers in neck handling in container treatment systems and can also be integrated into existing container transport routes.

This object is achieved by a transport device for transporting containers along a container transport route according to the features of independent patent claim 1 . Furthermore, to solve the problem, a container transport route for transporting containers according to the features of claim 18 and a method for transporting containers along a Container transport path specified according to the features of independent claim 19. The remaining patent claims relate to particularly advantageous developments of the invention.

According to an essential aspect, the invention provides a transport device for transporting containers along a container transport route.

The transport device comprises at least one transport star, the transport star having at least one first rotor-like transport element which is aligned in a first horizontal plane and can be driven continuously around a first vertical star axis. Distributed around the first star axis on the circumference of the first transport element are a plurality of first container carriers, each arranged at a first height and gripping the containers at a first gripping height, for hanging the containers. Furthermore, at least one first motor drive is provided for driving at least the first rotor-like transport element in rotation.

The invention is characterized in particular by the fact that the transport star has a second rotor-like transport element in addition to the first transport element. The second transport element is arranged or aligned in a second horizontal plane and can be driven continuously around a second vertical star axis, with a large number of container carriers, each arranged at a second height and gripping the containers at a second gripping height, being distributed around the circumference of the second transport element hanging holding of the containers are provided.

The first and second star axis are offset from one another and the transport elements partially overlap.

The at least one transport star of the transport device according to the invention advantageously has two rotor-like transport elements which are coupled to one another and work together. The transport elements of the transport stem can also be used as supporting structures running around or as supporting wheels or supporting disks or referred to as wheels, the two transport elements of the transport system being arranged one above the other in two horizontal planes and aligned in an overlapping manner with respect to one another such that the majority of their surfaces preferably overlap, but their arrangement deviates from a concentric arrangement. The overlap is for example at least 70% or at least 75% of the area of the respective transport elements, preferably at least 80% or 85%, particularly preferably at least 90% or 95% and particularly preferably around 96% of the area of the respective transport elements. In other words, the two transport elements of the transport stem are mounted eccentrically one above the other. The transport system can therefore also be referred to as a two-gyroscope star with eccentric rotors or as a double-gyroscope star with eccentric rotors, namely as an eccentric two-gyroscope star or double-gyroscope star, whereby due to the non-concentric and superimposed arrangement of the two transport elements, the peripheral shape of the transport system formed therefrom deviates from the circular shape.

During operation of the transport system, namely during rotation of the transport elements, the respective container carriers distributed on the circumference of each transport element each describe a circular path. In a projection view or in a top view, these circular paths of the container carriers intersect in two areas or points. In the area of these intersections of the circular paths described by the container carriers, respective container carriers of the first transport element coincide with respective container carriers of the second transport element during the circulation of the transport elements, so that in these areas a transfer or transfer of containers held hanging from the first transport element to the second transport element or vice versa from the second to the first transport element is possible.

Since the container carriers of the two transport elements of the transport system are arranged at different heights and are provided at different gripping heights for gripping the containers, according to the present invention the gripping area, in particular the gripping position or gripping height of the containers on the movement path of the containers within a single transport system, namely within of one and the same transport star. This means that on the movement path along a part of the circumference of the transport star wheel, there is a "change of grip", namely a change from "under the neck" gripping to "over the neck" gripping or vice versa. To a certain extent, the present transport device can also be referred to as an active clamp system or active interchangeable clamp system.

According to a preferred embodiment variant, a second motor drive or a gear-like coupling with the first motor drive is provided in order to drive the second rotor-like transport element.

The first and second rotor-like transport elements are preferably driven in a controlled manner and rotate synchronously in a common direction of rotation, with a control unit being provided for the drive control. In addition to the controller or as an alternative to the controller, a control device for controlling the movements or rotational movements of the transport elements can also be provided. In particular, a regulation is suitable for maintaining a synchronous sequence of movements of the transport elements even under changing load conditions.

Preferably, the first and second rotor-like transport element can be carried by a common support column. Alternatively, however, an outer support structure can be provided, with at least one of the two rotor-like transport elements being supported by the outer support structure.

The first and/or the second motor drive is preferably a hollow shaft motor. This proves to be particularly advantageous in variants in which both transport elements are carried by a common support column.

The non-concentric superimposed arrangement of the two transport elements is such that the first and second vertical star axes run parallel and at a specified axial distance from one another, i.e. the two star axes run with a specified axial offset or the transport elements have a specified axial offset on. The axial offset is such that it is ensured that during the circulation of the transport elements in the region of the intersections of the circular paths described by the container carriers, respective container carriers of the first transport element coincide with respective container carriers of the second transport element. At the same time, however, the extent of the axial offset should ensure that there is a sufficiently small or no overlap between the container carriers of the two transport elements at the inlet and outlet areas of the transport star, but that the respective container carriers of the transport elements are offset or “shifted” from one another in such a way that that at these inlet and outlet areas only the container carriers of one of the two transport elements on the circumference of the transport stem protrude or protrude in an accessible manner. As a result, incoming containers can advantageously be taken over by an upstream conveyor unit or an upstream conveyor element or a treatment station and the containers can be transferred to a downstream conveyor unit or a downstream conveyor element or a treatment station quickly, effectively and without problems.

The first and second rotor-like transport element are each advantageously designed as star wheels, with a diameter of the first star wheel and a diameter of the second star wheel preferably being the same, but not necessarily the same. Preferably, the center distance between the first and second vertical star axes is in a range of about 2.4% to 3.8% of the diameter of the star wheels, preferably in a range of about 2.7% to 3.4% of the diameter of the star wheels, most preferably in a range of about 2.9% to 3.2% of the diameter of the starwheels. The center distance is particularly preferably around 3.0% or 3.1% of the diameter of the star wheels.

As already mentioned above, the peripheral shape of the transport star, or of the entire arrangement forming the transport star, deviates from the circular shape due to the axial offset of the transport elements. A transport axis of the transport system intersects both the first and the second vertical star axis essentially perpendicularly, with a longitudinal extension running along the transport axis of the coupled and interacting transport elements of the transport system being greater than a width of the coupled and interacting transport elements running essentially perpendicular to the transport axis interacting transport elements. According to a preferred embodiment variant, the transport star has a take-over position in an infeed area for taking over the containers from a conveyor unit arranged along the container transport route in front of the transport star. The transport star also has a transfer position in an outlet area for transferring the containers to a conveying unit arranged downstream of the transport star along the container transport path. The transfer position is upstream of the transfer position with respect to a movement path of the containers running over part of the circumference of the transport system, with the transfer position being provided by the first transport element and the transfer position being provided by the second transport element, or vice versa, the transfer position being provided by the second transport element and the Transfer position is provided by the first transport element.

At least one first changing position is particularly preferably provided in an angular region of the transport system located on the path of movement of the containers between the transfer position and the transfer position, in order to enable the containers to be changed between the first and second transport element of the transport system. For this purpose, the transport system is configured to transfer the containers at the at least one first exchange position from the first transport element to the second transport element and/or from the second transport element to the first transport element.

The acceptance position and the transfer position are preferably arranged on opposite sides of the circumference of the transport stem, specifically essentially on opposite sides of the circumference in the direction of the transport axis. Here, the at least one first changing position is arranged in an angular range of around 90° starting from the transfer position on the circumference of the transport stem. If one now assumes that the path of movement of the containers along the circumference of the transport system from the takeover position to the transfer position covers an angular range of approximately 180°, the containers are transferred from one transport element to the other transport element at approximately half the path of movement. t element enough. Thus, the "change of grip", namely the change from "below the neck" gripping to "over the neck" gripping or vice versa, takes place at about half the movement path along the circumference of the transport stem.

The container carriers of the first and second rotor-like transport elements are preferably designed as passive or active gripping elements and are set up to grip around a neck area of the container. For example, the container carriers are designed in the form of container clamps, the container clamps being movable from at least one open position into at least one closed gripping position. A controller for the container clamps is particularly preferably provided for this purpose and the movement of the container clamps from the open position to the gripping position and vice versa from the gripping position to the open position is controlled. For example, each container clamp can comprise at least two gripping arms pivotably mounted on a support body, each container clamp being movable from the open position to the gripping position and vice versa from the gripping position to the open position by pivoting the gripping arms relative to one another.

The first and the second rotor-like transport element are advantageously arranged relative to one another in such a way that the transport system has at least one position in which a container carrier of the first transport element and a container carrier of the second transport element come to lie congruently one above the other, i.e. in relation to a vertical direction. This position is expediently the previously mentioned changing position. It is particularly preferred if the transport system has two positions in which a container carrier of the first transport element and a container carrier of the second transport element come to lie congruently one above the other.

The invention also includes a container transport route for transporting containers between at least two container treatment stations or container treatment machines of a container treatment plant, the container transport route having at least one transport device as described above. Furthermore, the invention also includes a method for transporting containers along a container transport route by means of a transport device which has at least one transport star. The transport star comprises at least one first rotor-like transport element, which is aligned in a first horizontal plane and can be driven continuously around a first vertical star axis, and has a large number of first container carriers for hanging holding, which are arranged at a first height and grip the containers at a first gripping height and are distributed around its circumference the container is provided. The transport system also includes a second rotor-like transport element which is designed to have the same circumference as the first transport element, is aligned in a second horizontal plane and can be driven continuously around a second vertical star axis, on the circumference of which a large number of transport elements are in turn distributed at a second height and the containers in a second container carrier reaching a second gripping height is provided for holding the containers in a hanging manner. The first and second star axis are offset from one another and the transport elements partially overlap. In the method, the containers are moved on a movement path over at least part of the circumference of the transport system. The method is characterized in particular by the fact that the containers are transferred between the first and second transport element at at least one changing position on the movement path of the containers, which runs partially around the circumference of the transport system, and the gripping height is thereby changed on the movement path of the containers.

The expression “substantially” or “approximately” means deviations from the respective exact value by up to +/-10%, preferably by up to +/-5%, and/or deviations in the form of changes that are insignificant for the function .

Further developments, advantages and possible applications of the invention also result from the following description of exemplary embodiments and from the figures. All of the features described and/or illustrated are fundamentally the subject matter of the invention, either individually or in any combination, regardless of how they are summarized in the claims or how they relate back to them. The content of the claims is also made part of the description. The invention is explained in more detail below with reference to the figures of exemplary embodiments. Show it:

1 highly simplified a container treatment plant known from the prior art in a diagrammatic plan view,

2 highly simplified in a diagrammatic plan view illustration a container treatment plant with a transport device according to an embodiment of the invention,

3 greatly simplified in a diagrammatic plan view illustration an alternative container treatment plant with a transport device according to an embodiment of the invention,

4 shows a roughly schematic plan view of a transport device according to an embodiment of the invention,

Fig. 5a - 5d only partially and schematically shown different views of a transport device according to an embodiment of the invention in the area of the container carrier of the transport elements,

Fig. 6 is a highly simplified diagrammatic plan view representation of a container transport line with a transport device according to an embodiment of the invention,

7 shows a roughly schematic sectional view of an embodiment variant of the transport device along the transport axis,

8 shows a roughly schematic sectional view of a transport device perpendicular to the transport axis, 9 shows a roughly schematic sectional view of a preferred embodiment of the transport device and

10 shows a roughly schematic sectional view of a further preferred embodiment of the transport device.

Identical reference symbols are used in the figures for elements of the invention that are the same or have the same effect. Furthermore, for the sake of clarity, only reference numbers that are required for the description of the respective figure are shown in the individual figures. The invention is also shown in the figures only as a schematic view to explain the mode of operation. In particular, the representations in the figures only serve to explain the basic principle of the invention. For reasons of clarity, all components of the device have not been shown.

1 shows a highly simplified, diagrammatic top view of a container treatment system 100 known from the prior art, which is used for blow molding, filling and sealing containers 2 (not visible in FIG. 1) in the form of plastic or PET bottles. The individual treatment stations or treatment machines or units provided for the respective container treatments are designed as revolving treatment stations or treatment machines and are arranged in a block together with a corresponding container treatment section S, which is used to transport the containers 2 between the treatment stations or treatment machines. that is to say the container treatment system 100 is implemented in a compact, in particular blocked, arrangement.

For this purpose, the container treatment system 1 comprises a blow molding machine 110 in which the containers 2 are produced by heating and stretch blow molding using preforms. The container treatment system 1 also includes a labeling machine 120, to which the containers 2 formed by blow molding are fed in a conveying or processing direction F by means of a first section of the container treatment section S. For this purpose, the container treatment line S several conveyor units 12, 12' arranged one behind the other, which are designed in the form of rotating star conveyors and which receive the containers 2 from the rotating treatment stations or treatment machines or pass them on to them. Neighboring rotating star conveyors 12, 12' rotate in opposite directions and the containers 2 are transferred from one star conveyor 12, 12' to the next at respective adjacent areas, in particular transfer areas or transfer points, so that the containers 2 on their movement path each have a path section along a respective part of the circumference of the star conveyors 12, 12'.

A filling machine 130 for filling the container 2 with the liquid product and a capping unit 140 for capping the filled container 2 are connected downstream of the labeling machine 120 in the conveying direction F, with the labeling machine 120 and the filling machine 130 also being several one behind the other over a further section of the container treatment line S arranged star conveyors 12, 12 'are connected. In an outlet area of the container treatment plant 100, the sealed containers 2 are forwarded to an external conveyor 150 and thus leave the area of the container treatment plant 100, for example.

The rotating star conveyors 12, 12' of the container treatment section S each have, for example, a spoked-wheel-like rotor which is driven to rotate about an associated vertical rotor axis and is preferably rotatably mounted on a vertical column, on the circumference of which is distributed at equal angular intervals around the rotor axis and at the same radial distance from the rotor axis, container receptacles or container carriers are present, which are not shown in FIG. 1 for reasons of clarity. The container receptacles or container carriers are provided, for example, as pincer-like grippers or retaining clamps, specifically for holding a container 2 in a hanging manner so-called neck rings (neck ring) 2.1 (see, for example, FIG. 5a). In order to enable the rotors of the star conveyors 12, 12' to "comb" in relation to their holding clamps and thus enable the containers 2 to be transferred from one star conveyor 12, 12' to the other star conveyor 12, 12', the rotors of these star conveyors 12, 12 'Not only driven synchronously and in opposite directions, but the retaining brackets of the star conveyor 12 are also in a different horizontal plane than the retaining brackets of the star conveyor 12'. In the case of the container treatment plant 100 shown, the holding clamps of the star conveyor 12 are arranged in a horizontal plane which lies somewhat above the horizontal plane of the holding clamps of the star conveyor 12'. In the example shown in FIG. 1, the star conveyors 12 marked with vertical hatching lines are designed as so-called “overneck” grippers with a gripping position above the neck ring 2.1, and the star conveyors 12′ marked with horizontal hatching lines are designed as so-called “lower neck "Gripper designed with gripping position below the neck ring 2.1.

In the case of the container treatment system 100 known from the prior art in the arrangement shown in Figure 1, in particular in the compact, interlocked design with the corresponding container transport section S consisting of the given arrangement of the star conveyors 12, 12', it is disadvantageous that in the labeling machine 120 so-called “neck handling”, in which the containers 2 can be held purely hanging, is not reliably possible, so that in the prior art in the labeling machine 120, the containers 2 are transported over the container bottom, namely “bottom handling”. must become. However, in addition to a loss of efficiency, this leads to a higher susceptibility to failure and, in particular, to enormous problems in the case of the material-saving lightweight PET containers that have recently been increasingly demanded.

This is where the present invention comes into play, which will now be described in more detail with reference to FIGS. From Figure 2 - in the same way of representation as in the example of Figure 1 - a container treatment system 100 can be seen, which also includes treatment stations or treatment machines, in a similar or the same design and arrangement as in the example of Figure 1, wherein the However, container transport route S of the container treatment plant 100 is equipped with a transport device according to the invention. In contrast to the example shown in Figure 1, in the container transport section S of container treatment system 100 in the example in Figure 2, there is a transport device with a Transport stem 1 provided according to the invention. As a result, the gripping height of corresponding container receptacles or container carriers 4, 6, namely grippers or clamps, is changed on the movement path of the container 2 along part of the circumference of the transport star wheel 1, as will be explained in more detail below in connection with FIGS. The transport starwheels 1 integrated in the two mentioned sections of the container transport path S can thus also be understood here as “changing” grippers, which are identified by cross-hatching in the example shown in FIG.

Due to the arrangement of the star conveyors 1 within the container transport path S shown, the star conveyors 12 immediately upstream and downstream of the labeling machine 120, namely the star conveyors 12, which transfer the containers 2 to the labeling machine 120, also differ from the example in FIG or take over from the labeling machine 120, formed by "Übemeck" - gripper with gripping position above the neck ring 2.1 (marked with vertical hatching lines). As a result, neck handling can be implemented in the labeling machine 120 with a given arrangement of the container transport path S, in particular while maintaining the given number of individual conveyor units, since this requires that the containers 2 be gripped "over the neck" with the gripping position above the neck -Ring 2.1 transferred to the labeling machine 120 or taken over by it.

This procedure makes it possible for the containers 2 to be held in the “lower neck” grip within the labeling machine. This is particularly advantageous since the forces which act on the container mouth during the labeling process result in the container being pressed more firmly into or onto the corresponding gripper by these forces, as a result of which the labeling process can be carried out reliably. By using the trans portsterne 1, the "bottom" handling of the containers within the labeling machine is made possible with an unchanged or reduced number of usual transport systems.

Due to the mechanical design of the blow molding machine 110 and filling machine 130 for the respective star conveyors 12 that are directly and directly connected to these machines 110, 130, the "overneck" gripping with gripping position above the neck ring 2.1, which is also specified or required, can be maintained or increased at the same time. be fulfilled.

FIG. 3 shows an alternative embodiment of a container treatment system 100 in which a transport device with a transport star wheel 1 according to the invention is integrated in the system to shorten the transport route, namely the container transport route S.

The transport device comprising at least one transport system 1 will now be described in greater detail in connection with FIGS. 4 and 5a-5d. The transport star 1 has a first rotor-like transport element 3, which is aligned in a first horizontal plane and can be driven continuously around a first vertical star axis SA1, and a second rotor-like transport element 5, which can be driven continuously around a second vertical star axis SA2. The second transport element 5 is aligned in a second horizontal plane.

Each of the two transport elements 3, 5 is essentially formed by a star wheel, the respective diameters of the first and the second star wheel 3, 5 being the same in the exemplary embodiment shown, although this is not mandatory. For the rotating drive of the star wheels 3, 5, at least one first motor drive 7 is provided, which is preferably effectively connected to the first star wheel or transport element 3.

On the circumference of the first transport element 3, distributed around the first star axis SA1 and arranged at the same radial distance from the first star axis SA1, there are a large number of container carriers 4 for hanging the containers 2, with the container carriers 4 each being arranged at a first height h1 are and grab the container 2 at a first gripping height, namely in particular above the neck ring 2.1. Similarly, on the circumference of the second transport element 5, distributed around the second star axis SA2 and arranged at the same radial distance from the second star axis SA2, a large number of container carriers 6 are provided for hanging the containers 2, which are each arranged at a second height h2 and namely, the containers 2 grip at a second gripping height, in particular below the neck ring 2.1.

The two transport elements 3, 5 are coupled or connected to one another in the transport star in such a way that they work together in such a way that the first and second star axes SA1, SA2 are offset from one another at a predetermined, defined axis distance d (see FIG. 7) and the transport elements 3, 5 partially cover. The transport elements 3, 5 are thus offset or shifted relative to one another along a transport axis TA in such a way that the coupled and interacting transport elements 3, 5 of the transport star wheel 1 have a longitudinal extent I along the transport axis TA which is greater by the center distance d than the diameter of the respective transport elements 3, 5 and therefore also by the center distance d is greater than a width of the coupled and interacting transport elements 3, 5 running essentially perpendicularly to the transport axis TA, which in turn corresponds to the diameter. During operation, namely when the transport elements 3, 5 rotate, they rotate synchronously, i.e. at the same rotational speed in a common direction of rotation R.

In an infeed area, the transport system 1 has a takeover position P2 for taking over the containers 2 from a conveyor unit 12, 12' or container treatment machine arranged along the container transport path S in front of the transport system 1. Similarly, the transport system 1 has a transfer position P2' in an outlet area for transferring the containers 2 to a conveyor unit 12, 12' or the container treatment machine arranged along the container transport route S after the transport system 1. The transfer position P2 is in relation to a part of the circumference of the Transportstems 1 running path of movement of the container 2 upstream of the transfer position P2 ', in the example shown the transfer position P2 by the first transport element 3 and the Transfer position P2 'is provided by the second transport element 5. It goes without saying that this is also possible vice versa in other embodiment variants.

Due to the design and arrangement of the transport elements 3, 5 with the respective container carriers 4, 6 arranged at different heights h1, h2, the containers 2 can be exchanged at at least one change position provided in an angular range of the transport star wheel 1 between the transfer position P2 and the transfer position P2' P1 are transferred from the first transport element 3 to the second transport element 5 (or vice versa). The gripping position can thus change or be changed on the movement path or the movement path of the container 2 along the transport star wheel 1 from the "overneck" grip to the "lower neck" grip or vice versa from the "lower neck" grip to the "overneck" grip. This means that the gripping position can be changed in one and the same transport star wheel on the way from the takeover at the takeover position P2 to the transfer at the transfer position P2'. Along the circumference of the transport star wheel 1, the containers describe a movement path that deviates from the ideal circular shape.

In the example shown, the takeover position P2 and the transfer position P2' come to lie approximately on the transport axis TA and thus enclose an angular range of around 180°. The changing position P1 is arranged in an angular range of approximately 90° starting from the transfer position P2. Opposite the changing position P1 there is a second changing position PT. A different arrangement of the respective acceptance and transfer positions P2, P2' and the changeover position P1 in relation to the angular ranges or angular positions is also possible. It is self-evident that not every existing change position necessarily has to be used to change the gripping position.

For better illustration, Figures 5b to 5d only show sections and schematically different views of the transport star 1 in the area of the container carriers 4, 6 of the transport elements 3, 5, specifically at the changing position P1 (and P1') (Figure 5b) and at the Transfer position P2 (Figure 5c; mirrored here in the illustration) and at the transfer position P2 '(Figure 5d). In figure 5a is a partial view of a neck area of the container with a neck ring 2.1, which is merely illustrative and is shown in isolation. The illustrations clearly show that the container carriers 4, 6 overlap at the changing position P1 (and PT), i.e. about halfway or movement path within the circumference of the transport star wheel 1 and overlap in such a way that it is possible to reach around and here the gripping area or the gripping position or gripping height can be changed, namely, for example, from the "over-the-neck" grip of the container carrier 4 to the "below-the-neck" grip of the container carrier 6.

The offset of the transport elements 3, 5 by the axial distance d also ensures that there is sufficient displacement of the container carriers 4, 6 at the takeover position P2 and at the transfer position P2' in order to transport the containers 2 unhindered and undisturbed by upstream star conveyors 12, 12 'Or machines, for example a labeling machine 120 or to hand over to downstream star conveyors 12, 12' or machines. FIG. 6 shows a very simplified representation of a top view of a container transport path S with an integrated transport device, with details and details being omitted for the sake of clarity. In particular, the container carriers 4, 6 are not shown in the figure.

The center distance d is matched to the diameter of the respective transport elements 3, 5, in particular star wheels 3.5, and is approximately 3.1% of the diameter in the example shown, with the diameter of the star wheels 3.5 being approximately 1620 mm and the center distance is about 50 mm.

With reference to FIGS. 7 to 10, preferred embodiment variants of the transport device are shown in different views, in particular sectional views, the basic design of the transport stem 1 of the transport device corresponding approximately to that of the overview shown in FIG. FIG. 7 is a sectional view of an embodiment variant of the transport device along the transport axis TA, thus a section through the pick-up and transfer position P2/P2'. FIG. 8 is a sectional view of a transport device perpendicular to the transport axis TA, ie a section through the changing positions P1/P1 FIGS. 9 and 10 are sectional views of respective embodiments of the transport device along section line CC drawn in FIG.

In the examples shown in Figures 7 and 8, a separate motor drive 7, 8 is provided for each of the transport elements 3, 5, which are carried by a common support column 9, with the motor drive 7 being effectively coupled or connected to the first transport element 3 . For the synchronous drive control of the motor drives 7, 8, in particular motors, a control unit 10 (not visible in FIGS. 7 and 8) is provided (see e.g. FIGS. 9 and 10), which is in communication with each of the motors 7, 8. In the variant of FIG. 8, an outer guide curve 13 is also provided for guiding the container.

As can be seen in particular from FIG. 9, the motors 7, 8 can be designed in the form of respective hollow-shaft motors or as double hollow-shaft motors. The common support column 9 is an inner support column, which is surrounded by the hollow shaft motors and is optionally provided with a cover 14, for example a protective or support cover. The control unit 10 communicates with each of the motors 7, 8 and synchronizes the drive.

FIG. 10 shows a further exemplary embodiment in which the second transport element 5 is carried by a support column 9 and the first transport element 3 is carried by an outer support structure 11. In this variant, too, the control unit 10 communicates with each of the motors 7, 8 and synchronizes the drive. Reference List

1 transport star

2 containers

2.1 neck ring

3 first rotor-like transport element

4 first container carrier

5 second rotor-like transport element

6 second container carrier

7 first motor drive

8 second motor drive

9, 9' support column

10 control unit

11 outer support structure

12, 12' conveyor unit

13 outer guide curve

14 disguise

100 container treatment plant

110 blow molding machine

120 labeling machine

130 filling machine

140 capping unit d center distance h1 first level h2 second level

R1 , PT change position

P2 transfer position

P2' transfer position

R direction of rotation

S container transport route

SA1 first star axis SA2 second star axis

TA transport axis

Claims

23 patent claims

1. Transport device for transporting containers (2) along a container transport route (S) with at least one transport star (1), wherein the transport star (1) has at least one device which can be driven continuously in a first horizontal plane and about a first vertical star axis (SA1). first rotor-like transport element (3), with a large number of first container carriers each arranged at a first height (h1) and gripping the containers (2) at a first gripping height distributed around the first star axis (SA1) on the circumference of the first transport element (3). (4) is provided for holding the containers (2) in a suspended manner and wherein at least a first motor drive (7) is provided for driving at least the first rotor-like transport element (3) in rotation, characterized in that the transport star (1) also has a Working relationship to the first transport element (3) formed, aligned in a second horizontal plane s and has a second, rotor-like transport element (5) that can be driven continuously around a second vertical star axis (SA2), with a large number of transport elements (5) distributed around the circumference of the second transport element (5), each arranged at a second height (h2) and the containers (2) in container carriers (6) reaching a second gripping height for hanging the containers (2), the first and second star axes (SA1, SA2) being offset from one another and the transport elements (3, 5) partially overlapping.

2. Transport device according to claim 1, characterized in that a second motor drive (8) or a gear-like coupling to the first motor drive (7) is provided in order to drive the second rotor-like transport element (5).

3. Transport device according to claim 1 or 2, characterized in that the first and second rotor-like transport element (3, 5) are driven in a controlled manner and rotate synchronously in a common direction of rotation (R), a control unit (10) being provided for the drive control. Transport device according to one of the preceding claims, characterized in that the first and second rotor-like transport element (3, 5) are carried by a common support column (9). Transport device according to one of claims 1 to 3, characterized in that an outer support structure (11) is provided and the first or the second rotor-like transport element (3, 5) is supported by the outer support structure (11). Transport device according to one of the preceding claims 2 to 5, characterized in that the first and/or the second motor drive (7, 8) is a hollow shaft motor. Transport device according to one of the preceding claims, characterized in that the first and second vertical star axis (SA1, SA2) run parallel and at a predetermined axis distance (d) from one another. Transport device according to one of the preceding claims, characterized in that the first and second rotor-like transport element (3, 5) are each designed as a star wheel, with a diameter of the first star wheel (3) and a diameter of the second star wheel (5) being the same. Transport device according to claim 7 and 8, characterized in that the center distance (d) between the first and second vertical star axis (SA1, SA2) is in a range of approximately 2.4% to 3.8% of the diameter of the star wheels (3, 5 ) is preferably in a range of about 2.7% to 3.4% of the diameter of the star wheels (3, 5), particularly preferably in a range of about 2.9% to 3.2% of the diameter of the star wheels (3 , 5) and particularly preferably around 3.0% or 3.1% of the diameter of the star wheels (3, 5). Transport device according to one of the preceding claims, characterized in that the transport system (1) has a transport axis (TA) which intersects both the first and the second vertical star axis (SA1, SA2) essentially perpendicularly, with a longitudinal extension (I) running along the transport axis (TA) of the transport elements (3, 5) of the transport star (1 ) is greater than a width of the coupled and cooperating transport elements (3, 5) running essentially perpendicularly to the transport axis (TA). Transport device according to one of the preceding claims, characterized in that the transport star (1) in an infeed area has a transfer position (P2) for taking over the containers (2) from a conveyor unit arranged along the container transport path (S) in front of the transport star (1) and that the transport system (1) has a transfer position (P2') in an outlet area for transferring the containers (2) to a conveyor unit arranged along the container transport route (S) after the transport system (1), the take-over position (P2) in relation to an over a part of the circumference of the transport system (1) running path of movement of the container (2) is upstream of the transfer position (P2'), the transfer position (P2) being carried out by the first transport element (3) and the transfer position (P2') being carried out by the second transport element ( 5) is provided or vice versa the takeover position (P2) by the second transport element (5) and the transfer position (P 2') is provided by the first transport element (3). Transport device according to claim 11, characterized in that in one on the movement path of the container

(2) at least one first changing position (P1) is provided between the takeover position (P2) and the transfer position (P2') of the transport stem (1) in order to allow the container (2) to be changed between the first and second transport element (3, 5) to allow the transport stem (1), wherein the transport stem (1) is configured to the container (2) at the at least one first changing position (P1) of the first transport element

(3) to the second transport element (5) and/or from the second transport element (5) to the first transport element (3). 26 Transport device according to Claims 11 and 12, characterized in that the takeover position (P2) and the transfer position (P2') are arranged on opposite circumferential sides of the transport stem (1), essentially on opposite circumferential sides in the direction of the transport axis (TA) and that the at least one first changing position (P1) is arranged in an angular range of around 90° starting from the transfer position (P2) on the circumference of the transport star (1). Transport device according to one of the preceding claims, characterized in that the container carriers (4, 6) of the first and second rotor-like transport elements (3, 5) are designed as passive or active gripping elements and are set up to grip a neck area of the container (2). Transport device according to one of the preceding claims, characterized in that the container carriers (4, 6) are designed in the form of container clamps, the container clamps being movable from at least one open position into at least one gripping position. Transport device according to Claim 15, characterized in that a control for the container clamps is provided and the movement of the container clamps from the open position to the gripping position and vice versa from the gripping position to the open position is controlled. Transport device according to one of the preceding claims, characterized in that the first and the second rotor-like transport element (3, 5) are arranged relative to one another in such a way that the transport star (1) has at least one position (P1, PT), preferably two positions (P1, PT ), in which a container carrier (4) of the first transport element (3) and a container carrier (4) of the second transport element (3) come to lie congruently one above the other. 27 container transport line (S) for transporting containers (2) between at least two container treatment stations or container treatment machines of a container treatment plant, wherein the container transport line (S) has at least one transport device according to one of the preceding claims 1 to 17. Method for transporting containers (2) along a container transport route (S) by means of a transport device with at least one transport star (1), the transport star (1) having at least one first rotor-like transport element (3) which can be driven to rotate about a first vertical star axis (SA1). , on the circumference of which a large number of first container carriers (4) arranged at a first height (h1) and gripping the containers (2) at a first gripping height are provided for hanging the containers (2), the transport star (1) also being provided a second rotor-like transport element (5) which is configured in an operative relationship to the first transport element (3) and can be driven continuously around a second vertical star axis (SA2), on the circumference of which is distributed a large number of containers arranged at a second height (h2). (2) second container carriers (6) gripping at a second gripping height for hanging the containers ( 2) is provided and wherein the first and second star axis (SA1, SA2) are arranged offset to one another, wherein in the method the containers (2) are moved on a movement path over at least part of the circumference of the transport star (1), characterized in that that at least one changing position (P1) on the movement path of the containers (2), which runs partially around the circumference of the transport system (1), a container transfer between the first and second transport element (3, 5) takes place and thereby on the movement path of the containers (2) the gripping height is changed.