The invention concerns a coupling device for articulated connection of two elements of a device for conveying and/or sorting piece goods, wherein the coupling device connects together an end of each of the two elements pivotably with respect, to at least one rotational axis in a plane to both sides, and the two ends lie diametrically opposite each other in a neutral position.
The invention furthermore concerns a device for conveying and/or sorting piece goods, with several elements for handling the piece goods and at least one coupling device which pivotably connects together a respective two of the series-arranged elements.
Such a device for conveying and/or sorting piece goods is for example a so-called sorter, such as a circular sorter. Such circular sorters are composed of series-arranged elements or trays for the individual piece goods, which run on a predefined track guided by rails in a similar fashion to a chain. These elements of the sorter are known as cells or sorting cells. In order to allow the elements to pass around curves, they must have a spacing which corresponds to the curve radius, so that the inner corners of corresponding elements do not collide with one another when travelling around a curve. For this, the individual elements are connected by means of coupling devices (also called couplings) which are arranged centrally on the cells in order to guarantee by their length the necessary spacing between the individual cells.
Conversely, this means that the spacing between adjacent elements is required only when passing around corresponding curves. On straight segments of a sorter, this spacing is not required. Since the level of possible sorting performance is determined not only by the speed of the sorter but also by the number of sorting elements relative to the sorting length, it is possible to shorten the coupling devices and hence increase the number of elements for the same sorter dimensions.
Publication DE 10 2016 104 943 A1 discloses a device for sorting piece goods, i.e. a sorter, with several sorting elements and at least one coupling device which pivotably connects together a respective two of the series-arranged elements. The coupling device is configured as a type of hinged coupling with two pivotably connected coupling parts which are attached to the corresponding ends of the elements.
Starting from this situation, it is an object of the present invention to indicate measures which allow even relatively closely packed elements of a device for conveying and/or sorting piece goods to be guided on curved tracks.
The object of the invention is achieved by the features of the independent claims. Advantageous embodiments are given in the subclaims.
Accordingly, the object is achieved by a coupling device for articulated connection of two elements of a device for conveying and/or sorting piece goods, wherein the coupling device connects together an end of each of the two elements pivotably with respect to a rotational axis in a plane to both sides, and the two ends lie diametrically opposite each other in a neutral position, wherein the coupling device is configured such that, starting from a respective central axis of the two ends, the rotational axis on a pivot movement in the direction of the one side lies on this one side of the central axes, and on a pivot movement in the direction of the other side lies on this other side of the respective central axis. In this way, it is guaranteed that the corresponding elements can be guided around tightly curved tracks even with a relatively, short coupling device. In particular, it is provided that the pivot movement of the coupling device always takes place about only one rotational axis. Often in such a coupling device, in the neutral position, the position of the rotational axis is not definitively established since the position of the rotational axis changes momentarily from the one side to the other, depending on the side on which the pivot movement takes place.
It is therefore an essential point of the invention that the position of the rotational axis for the pivot movement to the one side is different from the position of the rotational axis for the pivot movement to the other side, wherein the respective position of the rotational axis lies on the side in whose direction the pivot movement actually occurs, i.e. a corresponding kink movement.
According to a preferred embodiment of the invention, it is provided that the coupling device is configured, for the different positions of the rotational axis,
(a) to select these from two or more than two predefined positions, or
(b) to adjust these by shifting the rotational axis.
With alternative (a), usually a sudden change occurs between the predefined axis positions, whereas in alternative (b), a continuous shift of the current position of the rotational axis occurs.
According to a further preferred embodiment of the invention, it is provided that the coupling device has two coupling elements which have identical lengths and are pivotable in opposite directions. These are pivotably connected to each of the two ends of the elements, wherein the corresponding joints have a spacing at the respective end which corresponds to the length of the coupling elements.
In particular, it is provided that the coupling device is configured to form, with the two ends of is the element, a four-bar linkage. A four-bar linkage is usually described by two bearings with hinges of defined position, and three bars connected together pivotably via two further hinges, giving a four-bar coupling system with four rotary hinges. For use inside the coupling device, taking the image of the four-bar linkage, the respective lengths of the bars of the linkage and the spacing between the two bearings are all equal. Accordingly, when used within the coupling device, the four-bar linkage does not operate in the usual fashion as a crank arm, double arm or double crank, but such that each mounted bar runs parallel to the arrangement of the bearings, and the other two bars, i.e. the respective other mounted bar and the bar of the linkage formed by the other element, pivot parallel to each other optionally about the one or the other bearing. These may then be described as coupling elements which have identical lengths and can pivot in opposite directions.
Alternatively, it is provided that the coupling device comprises flexible coupling elements which connect the two elements pivotably together. This mechanism is known from a Jacob's ladder toy. The flexible coupling elements are in particular formed as straps. They run crosswise between the ends of the elements. In top view, this forms an intersection point which marks the corresponding rotational axis for the pivot movement of the coupling device. This rotational axis is displaceable, so that with this embodiment of the coupling device, the different positions of the rotational axis can be adjusted by shifting the rotational axis along the gap between the ends. For use with said successive coupling of elements or trays, chains, cables, straps or belts may be used.
According to another alternative embodiment of the invention, it is provided that the coupling device has or is formed as a double hinge in the manner of a swing door hinge. A swing door hinge or swing door strap has two spring-loaded straps and allows swing doors to pivot in both passage directions. Such doors are known for example as saloon doors familiar from Westerns. In this way, the position of the rotational axis for the pivot movement can be changed from the one side to the other.
According to yet a further preferred embodiment of the invention, it is provided that the spacing between the two elements when the two elements are moved out of the neutral position is determined only by components of the coupling device lying on the currently used rotational axis.
Furthermore, advantageously it is provided that the spacing A of the positions of the rotational axis on a pivot movement to the one side and to the other side is greater than the length 1 of the coupling device which determines the spacing between the ends of the corresponding elements.
The object of the invention cited initially is furthermore achieved by a device for conveying c and/or sorting piece goods with (i) several elements for handling the piece goods, and (ii) at least one coupling device which pivotably connects together a respective two of the series-arranged elements. It is provided here that the coupling device or at least one of the coupling devices, preferably all coupling devices, is/are configured as a coupling device as described above.
According to a preferred embodiment of the device according to the invention, it is provided that the width of the elements substantially corresponds to the spacing A of the different positions of the rotational axis. The position of the rotational axis therefore lies at a corner point on the side towards which the pivot movement is currently taking place.
According to a further preferred embodiment of the device according to the invention, it is provided that the device is configured as a sorter and/or distribution device known as a sorter. The following types of sorter are known: tilt tray sorter, belt tray sorter, sliding shoe sorter, drop flap sorter, comb sorter, helix sorter, circular sorter or ring sorter, and pocket sorter. Particular preferably, the device is configured as a circular sorter.
The invention is described in more detail below with reference to the appended drawings is showing preferred exemplary embodiments.
The drawings show:
The device 10 in this example is a sorting and/or distribution device known as a sorter. In such a device 10, the series-arranged elements 12 for handling the piece goods are moved on a track 22 guided by rails (corresponding to the depicted markings of the track 22), wherein the track 22 lies in one plane and has corners. In other words, the series arrangement of the elements 12 is guided on the track 22 on both sides, i.e. on both sides 24, 26, The elements 12 are here arranged very close together in series, and the coupling devices 14 are correspondingly short. Such a coupling device 14 is therefore described as a short coupling.
In order to be able to guide the elements 12 in this close succession around the corners, the coupling device 14 is configured such that, starting from a theoretical respective central axis 28 of the two elements 12, the rotational axis 20 on a pivot movement of the coupling device 14 in the direction of the one side 24 lies on this one side 24 of the respective central axis, and on a pivot movement of the coupling device 14 in the direction of the opposite other side 26 lies on this other side 26 of the respective central axis 24, The coupling device 14 thus forms a kind of change-over hinge, in which the position of the corresponding rotational axis 20 of this change-over hinge—i.e. the hinge axis—always lies on the side 24, 26 into which the corner points and the pivot movement provoked by the corner takes place. In the example shown here, there are precisely two predefined positions of the rotational axis 20, namely one on the one side 24 and one on the other side 26. In the present example, the rotational axis 20 for the two elements 12 lies in the middle on the one side 24, and on the other side 26 for the two elements on the right side of
In this depiction, it is furthermore clearly evident that the width B of the elements 12 substantially corresponds to the spacing A of the different positions of the rotational axis 20, i.e. in this embodiment of the coupling device 14, the spacing of the hinges 34, 38; 36, 40 at the respective ends of one of the coupling elements 30, 32.
In the embodiments of the coupling device 14 shown in
Several mutually coupled elements 12 may form an autonomous assembly in the manner shown. The individual elements 12 are here guided so that they cannot rotate about their vertical axis. However, the assembly can be stretched out. The corresponding guides are known in the prior art and are used in known sorters with successively arranged elements 12. The minimum radii—minimized by the design principle—during a motorized relative movement of the elements 12 enable such an assembly to advance along curvo-linear routes. In straight line portions, the adjacent elements 12 thus lie close together; in curved portions, they twist horizontally relative to each other via the rotational axes 20 with changing positions.
The exemplary embodiments described are merely examples which may be modified and/or supplemented in many ways within the scope of the claims. Each feature described for a specific exemplary embodiment may be used independently or in combination with other features in any other exemplary embodiment. Each feature described for an exemplary embodiment of a specific category may also be used accordingly in an exemplary embodiment of another category.
Number | Date | Country | Kind |
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102020108418.8 | Mar 2020 | DE | national |