The invention is explained in greater detail below by means of exemplary embodiments with reference to drawings in which:
While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will herein be described in detail one or more embodiments with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the invention to the embodiments illustrated.
The small-load carriers 14 are stacked on pallets 16.
The pallets 16 may be steel pallets, Europallets and/or Europallets on steel pallets.
The depalletising station 10 has a conveyor 18 with three conveyor belt regions 20, 22 and 24 arranged in a U-shape. The limb, on the right in
The conveyor 18 and the depalletising apparatus 12 are functionally connected to a control device (not shown) of the depalletising station 10.
The pallets 16 loaded with small-load carriers 14 can be supplied via the supply conveyor belt region 20 to the transfer conveyor belt region 24 in the direction of a first arrow 26 (supply-conveying direction 26), from the bottom upwards in
In the transfer conveyor belt region 24, the pallets 16 can be conveyed from the supply conveyor belt region 20 to the discharge conveyor belt region 22, from right to left in
The empty pallets 16 can be led away from the transfer conveyor belt region 24 via the discharge conveyor belt region 22 in the direction of a third arrow 30 (discharge-conveying direction 30), from the top downwards in
The supplied pallets 16 are loaded with small-load carriers 14 of different types, sizes, positions and orientations. Their uppermost layers thus have different setting patterns, seen from above. The small-load carriers 14 stand loosely on the pallets 16 and are thus undefined in their exact position. For example, situated in the uppermost layer on the pallet 16 which is ready for depalletising in the region of the depalletising apparatus 12, at the top left in
Running parallel to the transfer conveyor belt region 24 at a distance from the latter is a conveyor belt 32 which leads from the depalletising apparatus 12 in the direction of a fourth arrow 34 (conveyor belt direction 34), towards the right in
The depalletising apparatus 12 comprises a 6-axis industrial robot 36 with a gripping arm 38 and a gripping head 56.
The robot 36 stands on a pedestal 40, at the bottom left in
A flange 54 for the gripping head 56 is fastened to the free end region 52 of the gripping arm part 48. The flange 54 is pivotable about a fifth axis 58. The fifth axis 58 runs perpendicularly to the fourth axis. In the normal case, as illustrated in
The gripping head 56 hangs on the flange 54. The gripping head 56 has a stable frame construction, rectangular in the bottom view in
The axes have the effect that the spatial position of the gripping head 56 can be changed without its orientation in space, in particular the vertical orientation of the sixth axis 60, i.e. its inclination, changing. In particular, by suitable rotations about the corresponding axes, the gripping head 56 can be moved in and opposite the transfer-conveying direction 28 without its horizontal orientation being changed. In its starting position, the gripping arm 38 is oriented such that the gripping head 56 is positioned, with a preset maximum stack height, at a safe distance from the uppermost layer of small-load carriers 14 and the pallet 16 can be moved unimpeded into the region of the robot 36.
Furthermore, the gripping head 56 is designed such that it can tilt to a certain extent. It can thus compensate for skew positions of a small-load carrier 14 when the latter lies, on one side, with the step of its stacking edge on the upper edge of a neighbouring small-load carrier 14.
The gripping head 56, which is illustrated in detail in
The laser scanner 62 is situated on the outside of the transverse side, at the rear in the transfer-conveying direction 28, of the gripping head 56, pointing forwards in
The laser scanner 62 and the robot 36 are functionally connected to the control device in order to transfer the data acquired by the laser scanner 62 and to control the laser scanner 62 and the robot 36. Between the laser scanner 62, the robot 36 and the control device a protocol is agreed for data transfer and process control, in particular for a start and stop trigger for the scanning process and the robot movements and for outputting error messages.
The gripping device 64 is arranged on the bottom side of the gripping head 56. The small-load carriers 14 can be grasped on the pallets 16 by the gripping device 64, lifted by the gripping head 56 and, after suitable rotation of the rotary body 42 about the first axis, placed on the conveyor belt 32 by the gripping arm 38.
The gripping device 64 has (visible in particular in the bottom view in
An outer gripper displaceable on the longitudinal side (“longitudinal-side outer gripper” 70) is fastened so as to be displaceable, in
An outer gripper displaceable on the transverse side (“transverse-side outer gripper” 72) is fastened so as to be displaceable, in
The longitudinal guide rail 78 and the transverse guide rail 80 run at right angles to one another and are horizontally oriented in the case of normal orientation of the gripping head 56, as illustrated in
The transverse guide rail 80 is situated on the side of the gripping head 56 opposite the laser scanner 62.
The longitudinal-side outer gripper 70 and the transverse-side outer gripper 72 are movable proportionally to one another along the corresponding guide rail 78 and 80, respectively, by a servo motor 86 via an in each case endless longitudinal-side drive belt 82 and transverse-side drive belt 84, respectively, and in this way can be set with variable gripping distances for different-sized small-load carriers 14. The servo motor 86 is controllably connected to the control device.
The servo motor 86 is arranged on the transverse side opposite the laser scanner 62 at the corner of the gripping head 56 adjacent to the geometrical point of intersection of the two guide rails 78 and 80, above the gripping device 64 in the longitudinal-side view in
The longitudinal-side drive belt 82 runs outside the region defined by the four outer grippers 70, 72, 74 and 76, parallel to the longitudinal guide rail 78. It is guided on the transverse side of the gripping head 56 opposite the servo motor 86 via a longitudinal-side deflection roller 90, visible in
The transverse-side drive belt 84 runs, correspondingly, parallel to the transverse guide rail 80. A transverse-side deflection roller 92, which is visible in
When viewed laterally, the longitudinal-side drive belt 82 is arranged lower than the transverse-side drive belt 84, but this is not visible in the figures.
A fixed outer gripper 74, at the top right in
A longitudinal-side opposed gripper 76, at the bottom left in
The lifting and lowering device is connected to the longitudinal-side outer gripper 70 via a connecting strut 77, visible in
The lifting and lowering device is controllably connected to the control device. As long as the opposed gripper 76 is not required, for example when a small small-load carrier 14 is to be gripped, it is arranged in its rest position, illustrated in
All four outer grippers 70, 72, 74 and 76 are double grippers, that is to say they each have an outer gripping jaw 94 and an inner gripping jaw 96 which form a pair of gripping pincers open towards the small-load carriers 14, i.e. downwards in the normal case. The gripping jaws 94 and 96 have mutually parallel vertical gripping surfaces on their surface facing the respective other gripping jaw 96 and 94. The gripping jaws 94 and 96 are each fastened on a slide 98 visible in
The linear guides 100 of the transverse-side outer gripper 72, of the longitudinal-side outer gripper 70 and of the fixed outer gripper 74, and thus also the outer grippers 70, 72 and 74 themselves, are situated, in side view, at the same height at a fixed distance from the bottom side of the gripping head 56, in each case on the lower end face, facing away from the gripping head 56, of a respective approximately cuboid-shaped base body 102.
The linear guide 100 of the longitudinal-side opposed gripper 76 is situated below the carrier body 103 and is movable vertically with the latter.
The linear guides 100 of the longitudinal-side outer gripper 70, of the longitudinal-side opposed gripper 76 and of the fixed outer gripper 74 run in the transverse direction of the gripping head 56, i.e. parallel to the transverse guide rail 80. These outer grippers 70, 74 and 76 can grip the edges of a small-load carrier 14 which extend in the longitudinal direction of the gripping head 56, i.e. in the transfer-conveying direction 28.
The linear guide 100 of the transverse-side outer gripper 72 runs perpendicularly thereto in the longitudinal direction (
The outer gripping jaws 94 are arranged, in the bottom view in
The corresponding dimension of the gripping jaws 96 corresponds to the distance between the upper edge and the lower step-shaped termination of the stacking edge of a standardised small-load carrier 14; this is visible in
The gripping jaws 94 and 96 furthermore have an exchangeable gripping plate 104 on each of their gripping surfaces.
All the outer grippers 70, 72, 74 and 76 are pneumatically actuable, that is to say the slides 98 and hence the gripping jaws 94 and 96 can, in a manner known per se, via compressed air be pushed towards one another for gripping and held in this manner. In the pressure-free state, the gripping jaw pairs 94, 96 are each pushed apart by a compression spring (not shown). Each outer gripper 70, 72, 74 and 76 has, on the linear guides 100 for each of the gripping jaws 94 and 96, a pneumatic connection 106 for closing the grip. For the sake of clarity, the pneumatic connections 106 have been provided with reference symbols merely in
Furthermore, each outer gripper 70, 72, 74 and 76 has an initiator 108, shown in
In addition, all the outer grippers 70, 72, 74 and 76 have in each case a sensor 110, visible in
For depalletising a loaded pallet 16, the latter is firstly conveyed by the conveyor 18 to the depalletising apparatus 12 and placed in readiness there, for example with a tolerance of ±100 mm, in a region, which can be reached by the gripping head 56, at the end of the transfer conveyor belt region 24 (
As soon as the pallet 16 is situated at the end of the transfer conveyor belt region 24, i.e. the sight of the laser scanner 62 can no longer be obstructed by any previous pallet 16, a routine for determining the setting pattern of the uppermost layer of small-load carriers 14 is started. For this purpose, the gripping head 56 is firstly positioned by the robot 36 above the pallet 16 such that its longitudinal direction runs parallel to the transfer-conveying direction 28. The gripping head 56 is oriented here such that the laser scanner 62 is situated, viewed in the transfer-conveying direction 28, approximately centrally above the pallet 16 (
Subsequently, the gripping head 56 is moved opposite the transfer-conveying direction 28 at a constant speed horizontally above the pallet 16 without otherwise changing its orientation in space. During this, the uppermost layer of the small-load carriers 14 is continuously scanned by the laser scanner 62 in individual scanning slices (sectors). A three-dimensional surface profile of the load (setting pattern) is then calculated from the data thus acquired and is supplied to the control device. The control device uses an object recognition routine to detect from the setting pattern whether, which and at what position on the pallet 16 small-load carriers 14 are ready for gripping, in particular where and in what way their edges are running. If small-load carriers 14 are present, the data relevant to gripping, in particular their spatial position and their orientation, in particular their angles of rotation, relative to a coordinate system of the robot 36 are determined.
If defective small-load carriers 14 are detected during the scanning, provision may be made to output a fault message to an output unit (not illustrated) and to stop the depalletising process. After removing the defective small-load carrier 14, the process can be continued, in particular with renewed scanning of the uppermost layer.
It is also possible to detect that the small-load carriers 14 cannot be gripped and transmit this to the control device via an interface. For example, provision may be made to output an error message when parts of the load in the small-load carriers 14 are detected along the gripping positions which interfere with or even prevent their ability to be gripped. The fault can then be manually or automatically corrected. To restart the automatic depalletising process, the pallet 16 can be re-scanned to detect the setting pattern after the fault-clearing measures.
When all the data relevant to gripping is available, the robot 36 moves the gripping head 56 over the small-load carrier 14 to be gripped, at least two of the four side walls of which are free, i.e. grippable. Preferably, this is a small-load carrier 14 at the edge of the uppermost layer.
The gripping head 56 is arranged here such that the fixed outer gripper 74 is positioned in the corner region of a freely accessible side wall of the small-load carrier 14. The longitudinal-side outer gripper 70 and the transverse-side outer gripper 72, driven by the servo motor 86 with the corresponding drive belts 82 and 84 respectively, are moved relative to the small-load carrier 14, along the longitudinal guide rail 78 and the transverse guide rail 80 respectively, into their respective position for gripping the corresponding edge of the small-load carrier 14.
As soon as the sensors 110 detect that the outer grippers 70, 72 and 74 are in their gripping position, i.e. the respective gripping jaws 94 and 96 are positioned at the suitable distance in pairs on both sides of the respective edge, the corresponding pneumatic connections 106 for closing the outer grippers 70, 72 and 74 are supplied with compressed air and the fixed outer gripper 74, the longitudinal-side outer gripper 70 and the transverse-side outer gripper 72 are closed. The corresponding edges are then firmly clamped between the gripping jaws 94 and 96. A corresponding signal is produced by the initiators 108 and supplied to the control device.
The small-load carrier 14 now gripped at two side walls by three outer grippers 70, 72 and 74 is lifted by the height of the stacking edge, for example by about 20 mm, to enable the closure of the opposed gripper 76. In this process, the opposed gripper 76 is lowered by its lifting and lowering device to the height of the other outer grippers 70, 72 and 74, so that it can grip the edge corresponding to it analogously to the other outer grippers 70, 72 and 74. Its initiators 108 and sensors 110 transmit its correct position to the control device here.
For smaller small-load carriers 14 it is possible to do without the gripping of the opposed gripper 76. In this case, the opposed gripper 76 is not lowered.
The gripping head 56 with the small-load carrier 14 is now lifted further, so that the bottom of the latter is above the edges of the neighbouring small-load carriers 14, and the rotary body 42 with the gripping arm 38 is rotated horizontally until the gripping head 56 is positioned above the conveyor belt 32. During this, the longitudinal direction of the gripping head 56 is oriented in the conveyor belt direction 34. For this purpose, the gripping head 56 is correspondingly rotated by the flange 54 horizontally about the sixth axis.
The small-load carrier 14 is then deposited on the conveyor belt 32. This is detected by a light barrier 131 shown in
The pressure to the pneumatic connections 106 is then switched off by the pressure device, in order to open the outer grippers 70, 72, 74 and 76.
Finally, the gripping head 56 is lifted by the gripping arm 38 and moved back to the pallet 16 again, in order to grip the next small-load carrier 14.
In this way, all the small-load carriers 14 of the uppermost layer are successively depalletised.
After that, the process is repeated, starting with the scanning process of the respectively next uppermost layer, until the pallet 16 is completely unloaded.
As soon as the pallet 16 is empty, it is conveyed in the next conveying cycle to the discharge conveyor belt region 22 and by the latter to the pallet store, and the next loaded pallet 16 is conveyed by the transfer conveyor belt region 24 to the depalletising apparatus 12, where it is unloaded as described above. At the same time, the following loaded pallets 16 are transported to the transfer conveyor belt region 24 by the supply conveyor belt region 20.
Tests have shown that the unloading of, for example, 10 small-load carriers 14 takes about 80 seconds in the practical exemplary embodiment. The entire depalletising process, including the scanning process and the evaluating and transmission time for the data, amounts to about 90 seconds. Allowing for conveying and changing times for pallets 16, it is thus possible to depalletise on average about 6 small-load carriers 14 per minute.
In the case of an alternative exemplary embodiment (not illustrated), the laser scanner 62 may be arranged separately from the gripping head 56 rather than on it and may be movable via its own sensor axis by a drive motor separately from the gripping head 56 to scan the pallet 16.
In this case, the coordinate system of the robot 36 can be aligned before the scanning process with a coordinate system of the laser scanner 62, for example using reference marks. The reference marks are preferably situated on the pallet 16. They define in each case master positions both for the robot 36 and for the laser scanner 62.
The spatial position and orientation of the small-load carrier 14 ascertained during scanning is then compared with one of the master positions situated in the vicinity of the current positional point of the small-load carrier 14. From the comparison, a positional correction with respect to the corresponding reference mark is calculated and communicated to the robot 36. In this way, a positional error of the gripping head 56 relative to the laser scanner 62 is partially compensated. A positional drift of the gripping head 56 can be determined by cyclic referencing. In the practical example, the coordinate systems of the laser scanner 62 and of the robot 36 may be coordinated with one another such that an accuracy of about ±2 mm can be achieved. In this way, it is possible to scan scanning fields with areas of about 1250 mm×850 mm and greater with the laser scanner 62 at a distance of about 900 mm from the uppermost pallet layer.
In all the exemplary embodiments described, all the faults which occur during the scanning process can be recorded and displayed by a memory and output unit (not shown), in particular a personal computer. In addition, the fault messages can be logged by date and time in a file on the memory and output unit. The picking-up of small-load carriers 14 which have not been identified by the laser scanner 62 can also be logged on the memory and storage unit by date, time and the reason for the non-identification.
The apparatus and the process may, with appropriate modification, also be used for palletising containers, in particular small-load carriers 14.
Instead of small-load carriers 14, other standardised or non-standardised containers having a grippable edge may also be palletised or depalletised.
The small-load carriers 14 on a pallet 16 may be identical or different. The setting patterns may be predefined.
Instead of ascertaining the setting pattern of all the small-load carriers 14, it is also possible to determine only the position and orientation of the respective small-load carrier 14 to be gripped.
Instead of pallets 16, other kinds of carrier devices may also be used.
A plurality of sensor devices, in particular laser scanners 62, may also be provided.
The gripping device 64 may also have only one outer gripper or more than four outer grippers 70, 72, 74 and 76. Outer grippers for optional retrofitting may also be provided.
Each of the outer grippers 70, 72, 74 and 76 may also be realised, not as double grippers, but as triple grippers with three gripping jaws 94, 96, by which two edges running perpendicularly to one another at a corner of the container can be gripped simultaneously.
Furthermore, one or more outer grippers 70, 72, 74 and 76 may have a gripping-force safeguard or a means for engaging underneath, which safeguard or means ensures that the gripped edges do not slip out.
The laser of the laser scanner 62 may also emit light in the non-visible wavelength range.
Instead of the laser scanner 62, there may also be provided another kind of sensor device, in particular optical, with which, for example, colours can also be detected.
The sensor device may also be designed such that it can detect the colour of the small-load carriers 14 as an additional identification feature.
It is to be understood that additional embodiments of the present invention described herein may be contemplated by one of ordinary skill in the art and that the scope of the present invention is not limited to the embodiments disclosed. While specific embodiments of the present invention have been illustrated and described, numerous modifications come to mind without significantly departing from the spirit of the invention, and the scope of protection is only limited by the scope of the accompanying claims.
Number | Date | Country | Kind |
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102006018502.1 | Apr 2006 | DE | national |