MAGAZINE STORAGE UNIT FOR STORING SMALL PARTS, STORAGE ARRANGEMENT, AND METHOD FOR COMMISSIONING WITH THE MAGAZINE STORAGE UNIT

Abstract

It is known that in particular components or component accessories are stored in a storage in industrial production. To this end, a depot storage unit for storing small parts is proposed, having a base frame, a rotary table, wherein the rotary table is rotatably supported on the base frame and is rotatable relative to the base frame and wherein the rotary table includes a base plate, a drive device, wherein the drive device is operatively connected to the rotary table, so that the drive device rotates the rotary table, a plurality of receiving boxes, wherein the receiving boxes are arranged on the base plate in the direction of rotation, wherein the depot storage unit includes at least or exactly one sensor device for detecting a weight of at least or exactly one of the receiving boxes.

Claims

1-15. (canceled)

16. A depot storage unit for storing small parts, comprising: a base frame, a rotary table, wherein the rotary table is rotatably supported on the base frame and is rotatable relative to the base frame about an axis of rotation and wherein the rotary table has a base plate, a drive device, wherein the drive device is operatively connected to the rotary table, so that the drive device rotates the rotary table about the axis of rotation, a plurality of receiving boxes, wherein the receiving boxes are arranged on the base plate in the direction of rotation, wherein the depot storage unit includes at least or exactly one sensor device for detecting a weight of at least or exactly one of the receiving boxes.

17. The depot storage unit according to claim 16, wherein the sensor device remains stationary relative to the base frame when the rotary table is rotated.

18. The depot storage unit according to claim 16, wherein the depot storage unit includes a lifting device, wherein at least or exactly one of the receiving boxes is able to be lifted from the base plate by the lifting device, wherein the lifting device remains stationary relative to the base frame when the rotary table is rotated.

19. The depot storage unit according to claim 18, wherein the lifting device is designed as a rocking lever mechanism, wherein the lifting device includes an adjustment actuator and a lever arm with a support portion, wherein the lever arm is adjustable when the adjustment actuator is operated, so that one of the receiving boxes is moved over the support portion.

20. The depot storage unit according to claim 18, wherein the lifting device includes the sensor device, wherein, while lifting one of the receiving boxes, the weight of the receiving box that is lifted is able to be detected by the sensor device.

21. The depot storage unit according to claim 16, wherein, in order to remove small parts, at least or exactly one of the receiving boxes is able to be arranged at a removal site, wherein the sensor device and/or the lifting device are arranged at the removal site.

22. The depot storage unit according to claim 16, wherein the rotary table has a circumferential rim portion, wherein the drive device is arranged radially within the rim portion and is operatively connected to the rim portion, wherein the drive device remains stationary relative to the rotary table when the rotary table is rotated.

23. The depot storage unit according to claim 16, wherein the depot storage unit includes a further sensor unit, wherein an angular rotation position of the rotary table is able to be detected by the further sensor device.

24. The depot storage unit according to claim 16, wherein the depot storage unit has a casing, wherein the receiving boxes are arranged within the casing, wherein the casing has a removal opening, wherein the removal opening constitutes the or a further removal site for one of the receiving boxes, wherein the other receiving boxes are covered by the casing, and wherein the casing remains stationary relative to the rotary table when the rotary table is rotated.

25. A storage arrangement, comprising a depot storage unit according to claim 16.

26. The storage arrangement according to claim 25, wherein the storage includes at least one further depot storage unit, wherein each of the depot storage units has a lower and an upper interface in each case, wherein the upper interface of the one depot storage unit is complementary to the lower interface of the other depot storage unit in each case, so that a multistory rotary storage is able to be created.

27. The storage arrangement according to claim 25, wherein the storage arrangement includes an input device, wherein the input device is connected to the depot storage unit and/or the rotary storage by signaling technology, wherein the input device is designed to control and/or display information of the depot storage unit and/or the rotary storage.

28. The storage arrangement according to claim 27, wherein a sequence of different angular rotation positions is able to be determined by means of the input device, so that the receiving boxes are made available in a determined order.

29. The storage arrangement according to claim 27, wherein the input device is designed to display and/or check a filling level of the receiving boxes based on the weight, wherein the input device outputs a notification in case of deviation of a maximum and/or a minimum filling level value.

30. A method for order picking using the depot storage unit according to claim 16, in which: the drive device rotates the rotary table relative to the base frame about the axis of rotation, wherein the sensor device detects a weight of at least or exactly one of the receiving boxes at least during a standstill of the rotary table.

Description

[0060] Further features, advantages and effects of the invention result from the following description of preferable exemplary embodiments of the invention. Therein:

[0061] FIG. 1 shows a three-dimensional representation of a storage arrangement as an exemplary configuration of the invention;

[0062] FIG. 2 shows a plan view of a depot storage unit of the storage arrangement;

[0063] FIG. 3 shows the depot storage unit in a schematic representation with an evaluation device;

[0064] FIG. 4 shows a sectional view of the depot storage unit of FIG. 2;

[0065] FIG. 5 shows a further sectional view of the depot storage unit of FIG. 2;

[0066] FIG. 6a-c shows different user interfaces of an input device of the storage arrangement of FIG. 1.

[0067] Parts that correspond to each other or are identical are marked with the same reference signs in the figures.

[0068] FIG. 1 shows in a three-dimensional representation a storage arrangement 1, where storage arrangement 1 has a rotary storage 2 and an input device 3. The rotary storage 2 is used in particular for storing small parts, e.g. screws, component parts, etc. The rotary storage 2 has a depot storage unit 4 and four further depot storage units 5, wherein the depot storage unit 4 forms a first story E1 and the further depot storage units 5 form a second to fifth story E1-5.

[0069] The depot storage units 4, 5 each have a base frame 6, a rotary table 7 and several receiving boxes 8 arranged on the rotary table 7. The receiving boxes 8 have a circle segment-shaped base area and are arranged in a circle in the direction of rotation with respect to the axis of rotation D. For example, the receiving boxes 8 all have the same bulk volume. Alternatively, however, some of the receiving boxes 8 may have a different bulk volume from the rest. For example, the receiving boxes 8 or some of the receiving boxes 8 have a bulk volume of 0.3 litres or 1.8 litres or 4.6 litres.

[0070] The rotary table 7 can be rotated relative to the base frame 6 about the rotation axis D, wherein the base frame 6 remains stationary. The individual base frames 6 of the depot storage units 4, 5 are firmly connected to each other, wherein the depot storage unit 4 is connected to a stand 6. For example, each of the depot storage units 4, 5 can be operated independently of the others.

[0071] The two further depot storage units 5 on the second and third levels E2, E3 each have a casing 10. For example, the casing 10 is connected to the base frame 6, so that the casing 10 remains fixed to the frame when the rotary table 7 is rotated. The casing 10 is designed as a cylindrical casing, wherein the casing 10 is interrupted in the direction of rotation, thus forming a removal opening 11 in the casing 10. For example, the removal opening 11 can be additionally closed or covered by a closing device, not shown.

[0072] The depot storage units 5 each have a removal site 12 for removing small parts from one of the receiving boxes 8. The removal sites 12, for example, are all arranged one above the other at the same position. For example, the small parts can be removed manually at the removal site 12. In particular, the removal opening 11 forms the removal site 12 of the second and third stories E2, E3. The receiving boxes 8 are arranged inside the casing 10, wherein the receiving box 8 arranged at the removal site 12 is freely accessible. The remaining boxes 8 are covered by the casing 10, so that access to them is prevented. For example, the removal sites 12 can each be additionally illuminated by a light source, not shown, so that the receiving box 8 located at a removal site 12, in particular the contents thereof, is illuminated. This also allows a clear identification of the removal site 12 to be realized. The input device 3 serves in particular to control and/or display information from the rotary storage 2 or at least one of the depot storage units 4, 5. For this purpose, the input device 3 is connected to the rotary storage 2 with signalling technology, for example via a wireless connection. For example, the input device 3 may be designed as a portable computer, in particular a smartphone or tablet.

[0073] FIG. 2 shows the depot storage unit 4, from FIG. 1, in an axial plan view in relation to the axis of rotation D. The base frame 6 can consist of several individual circle segment-shaped sheet metal components, so that the base frame 6 has at least an approximate circular ring-shaped contour in a projection from above.

[0074] The depot storage unit 4 has a drive device 13, wherein the drive device 13 is arranged radially with respect to the axis of rotation D within the base frame and is connected to it in a rotationally fixed manner. The drive device 13 is drive-connected to the rotary table 7 so that the drive device 13 rotates the rotary table 7 in the direction of rotation with respect to the axis of rotation D. The drive device 13 comprises an engine 14, e.g. an electric engine, and a transmission device 15, wherein a driving torque is generated by the engine 14 and transmitted via the transmission device 15 to the rotary table 7.

[0075] The depot storage unit 4 has a lifting device 16, wherein the lifting device 16 has an adjustment actuator 17, a lever arm 18 and a support portion 19. The support portion 19 is located at the end of the lever arm 18. The lifting device 16 is located inside the base frame 6 with respect to the axis of rotation D and is firmly connected to it. The lifting device 16 is used to lift or lower one of the receiving boxes 8. The support portion 19 has four support pins 20, wherein the receiving box 8 rests on the support pins 20 when lifted or lowered. The lifting device 16 is located at the removal site 12. For example, the lifting device 16 makes one of the receiving boxes 8 available at the removal site 12 by lifting.

[0076] Furthermore, the depot storage unit 4 has a sensor device 21, wherein the sensor device 21 is designed to detect a weight of exactly one of the receiving boxes 8. Preferably the lifting device 16 has the sensor device 21. The sensor device 21 is operatively connected to the support portion 19, so that when the receiving box 8 is lifted, a weight force of the receiving box 8 is transferred to the sensor device 21 via the support portion 19. For example, the sensor device 21 is designed as a load cell.

[0077] The depot storage unit 4 has a further sensor device 22, wherein the further sensor device 22 is located within the base frame 6. The further sensor device 22 is used to detect a rotation angle position of the rotary table 7. For example, the sensor device 22 is designed as an incremental encoder, wherein the sensor device 22 detects a change in the angular rotation position. The base frame 6 has several rollers 23 evenly distributed in the direction of rotation, wherein the rotary table 7 is rotatably mounted on the base frame 6 via the rollers 23. When the rotary table 7 is rotated, the drive device 13, the lifting device 16 as well as the sensor device 21 and the other sensor device 22 remain stationary relative to the base frame 6.

[0078] FIG. 3 shows the depot storage unit 4 in a highly simplified schematic representation. The depot storage unit 4 has an evaluation device 24, wherein the input device 3, the drive device 13, the lifting device 16, the sensor device 21, the further sensor device 22 and at least one lighting device 25 are connected to the evaluation device 24 with signalling technology.

[0079] For example, when calibrating the depot storage unit 4, an empty weight from each of the receiving boxes 8 can be detected by the sensor device and stored in the evaluation device 24. Optionally in addition to this, the further sensor device 22 may detect the associated angular rotation position of the weighed receiving box 8, so that each receiving box 8 is stored with a unique angular rotation position and the associated empty weight in the evaluation device 24.

[0080] After the calibration phase, the receiving boxes 8 can be filled so that the receiving boxes 8 are loaded with an additional filling weight. Thus, the empty weight and the filling weight result in a total weight that can be detected by the sensor device 21. The sensor device 21 transmits the detected total weight to the evaluation device 24, wherein the filling weight of the receiving box 8 can be determined on the basis of the total weight. For this purpose, for example, the stored empty weight of the receiving box 8 is subtracted from the total weight, wherein the value of the difference corresponds to the filling weight.

[0081] The evaluation device 24 can then determine the filling level of the weighed receiving box 8, for example, on the basis of the filling weight. For example, a maximum value for the filling weight can be defined for this purpose, wherein the filling level can be determined on the basis of a difference between the maximum value and the calculated filling weight. Alternatively, exactly one article type is assigned to each of the receiving boxes 8, wherein each part of the article type is identically designed. For example, the weight per piece for each article type can be stored in the evaluation device 24, wherein a number of the small parts arranged in the associated receiving box 8 can be calculated on the basis of the filling weight and the weight per piece.

[0082] The evaluation device 24 can output an actuation signal for the drive device 13 and/or the lifting device 16 on the basis of the detected angular rotation position. For example, to rotate the rotary table 7 from an ACTUAL angular rotation position to a TARGET angular rotation position, a first actuation signal is output by the evaluation device 24. For example, the support portion 19 can be lowered and then the rotary table 7 can be rotated in the direction of rotation by the drive unit 13. When the TARGET angular rotation position is reached, this is detected by the other sensor device 22. Based on the detected TARGET angular rotation position, a second actuation signal is output by the evaluation device 24. For example, the support portion 19 and thus the receiving box 8 can be lifted so that the weight can be detected by the sensor device 21. Thus, an ACTUAL position is reached again, wherein the steps described can be repeated as often as required.

[0083] For example, individual receiving boxes 8 can be selected via the input device 3. Based on the associated angular rotation positions, the drive device 13 rotates the rotary table 7 until the selected receiving box 8 is located, for example, at the removal site 12 as shown in FIG. 1. As an alternative or optional supplement, the input device can be used to set, for example, the luminous intensity and/or the colour of the lighting device 25.

[0084] FIG. 4 shows a longitudinal section through the lifting device 16 along the axis of rotation D of the depot storage unit 4 of FIG. 2. The rotary table 7 has a base plate 7a and a surrounding rim portion 7b. The rim portion 7b extends in the axial direction with respect to the axis of rotation D in the direction of the base frame 6. The base frame 6 is arranged in the radial direction with respect to the axis of rotation D within the rim portion 7b, with the rim portion 7b closing the base frame 6 in the radial direction. The rim portion 7b is flush with an outer edge of the base plate 7a, wherein the rim portion 7b can, for example, be designed as a separate component and is connected to the base plate 7a in a positive and/or material and/or frictional and/or non-positive manner.

[0085] The rim portion 7b may have toothing 26 on its radial inner side with respect to the axis of rotation D, the toothing 26 extending completely in the circumferential direction with respect to the axis of rotation D. For example, the toothing 26 serves as a measuring standard for the further sensor device 22. For example, the further sensor device 22 is designed as a gear wheel encoder, so that the further sensor device 22 can determine the position of the angle of rotation by scanning the toothing 26.

[0086] The base plate 7a has a circular base area, with the receiving boxes 8 resting on the base plate 7a. The base plate 7a is mounted coaxially to the axis of rotation D on the base frame 6, with the base plate 7a resting on the rollers 23 for this purpose. Furthermore, the base plate has a number of receiving openings 27 to receive the support pins 20. For example, each of the receiving boxes 8 is assigned four of the receiving openings 27.

[0087] The lever arm 18, for example, is designed as a bending beam and/or is mounted via a swivel joint to rotate about a rotation point DP within the base frame 6. When the lifting device 16 is actuated, the adjustment actuator 17 applies a positioning force to the lever arm 18 in the axial direction with respect to the axis of rotation D, so that the lever arm 18 rotates about the rotation point DP. The support portion 19 is located below the base plate 7a, wherein when the receiving box 8 is lifted or lowered, the support pins 20 are each guided through one of the corresponding receiving openings 27. The receiving box 8 rests mainly on the support pins 20, wherein the receiving box 8 is completely spaced from the base plate 7a when lifted. This means that only the weight of the lifted receiving box 8 acts on the sensor device 21 via the support portion 19, so that an exact detection of the weight is achieved. During rotation of the rotary table 7, the support pins 20 are arranged outside the receiving openings 27 so that the rotary table 7 can be rotated unhindered in the direction of rotation.

[0088] The base frame 6 has an upper and a lower interface 6a, b, wherein the two interfaces 6a, b are each complementary with further interfaces of the other depot storage units 5. For example, the basic frames 6 of all depot storage units 4, 5 are identical in construction, so that, for example, the lower interface 6a of the depot storage unit 4 is complementary to an upper interface of the other depot storage unit 5. Thus, the number of depot storage units 4, 5 of the rotary storage 2 of FIG. 1 can be varied as desired. For example, the two interfaces 6a, b each have several connecting elements 28, wherein the connecting elements 28 form contour partners amongst each other. For example, the individual depot storage units 4, 5 can be connected to each other via a plug/turn connection. Thus, a positive and/or non-positive and/or frictional connection between the interfaces 6a, b of the depot storage units 4, 5 can be achieved. As an optional supplement, data can be exchanged via the two interfaces 6a, b, e.g. via a contact plug.

[0089] FIG. 5 shows a longitudinal section through the drive unit 13 in the same manner as FIG. 4. The transmission device 15 has a transmitting means 29, wherein the transmitting means 29 transmits the drive torque of the engine 14 to the rotary table 7. For example, transmission device 15 is designed as a belt drive, wherein the transmission means 29 is designed as a toothed belt or flat belt etc. The transmitting means 29 is operatively connected to the rim portion 7b, wherein a torque path runs from the engine 14 via the transmitting means 29 to the rim portion 7b. For example, the transmission device 15, in particular the transmitting means 29, is frictionally and/or non-positively connected to the rim portion 7b.

[0090] FIGS. 6a, b, c show different variants of the user interface of input device 3. In the example shown, input device 3 is designed as a smartphone, wherein the user interfaces can be part of a program, in particular application software.

[0091] FIG. 6a shows a main menu of the program, wherein the main menu shows a first window portion F1 and a second window portion F2. In the first window portion F1, several of the rotary storages 2 are shown as buttons, wherein the number of buttons can vary depending on the number of available rotary storages. In the design example shown, the storage arrangement 1, for example, has four of the rotary storages T1 to T4, wherein one of the rotary storages T1 to T4 can be selected via the button. By selecting the rotary storages T1 to T4, the selected rotary storage is displayed enlarged in the second window portion F2. The individual stories E1 to E5 are also displayed as buttons and can be selected via these, wherein the number of buttons can vary depending on the number of stories available.

[0092] Selecting one of the stories E1 to E5 opens a first window, as a submenu, which is shown in FIG. 6b. In the first window, one of the stories E1 to E5 is shown in a top view. All receiving boxes 8 of the selected story E1 to E5 are shown as circle segments K. The individual circle segments K are also designed as buttons so that each of the receiving boxes 8 can be selected individually. For example, the receiving boxes 8 can be colour-coded, wherein, for example, the circle segments of the freely assignable receiving boxes 8 have a different colour than the circle segments K of the already assigned receiving boxes 8. As an alternative or optional addition, a playlist can be created in the first window. For this purpose, a sequence of selected receiving boxes 8 can be defined, wherein the sequence can then be played back. In this case, the selected receiving boxes 8 are provided one after the other, for example, at the removal site 12.

[0093] By selecting one of the circle segments K, it is enlarged and a first option button 01 opens. For example, the first option button 01 shows the filling level of the selected receiving box 8 as number of pieces or filling weight. For example, a second option button 02, which is located centrally in the middle of the screen of the input device 3, displays the name of the selected receiving box, which is uniquely assigned to the selected receiving box. Preferably, by selecting one of the circle segments K, a signal is transmitted to the evaluation device 24, so that the rotary table 7 is turned and the selected receiving box 8 is made available at the removal site 12. A third and a fourth option button 03, 04 are located at the top of the first window. The third option button 03 is used, for example, to display an article description of the selected receiving box 8. The fourth option button 04 is used, for example, to display an article number of the selected receiving box 8.

[0094] The first window also has a fifth option button 05, the fifth option button 05 being designed as a button. The fifth option button 05 can be used, for example, for article assignment, wherein each of the receiving boxes 8 is assigned exactly one article type. By selecting the fifth option field 05, the corresponding article type, in particular the corresponding article number and/or the article description, is assigned to the selected receiving box 8.

[0095] FIG. 6c shows a second window, as a further submenu, which opens, for example, during a removal. Here, for example, the selected circle segment K of FIG. 6b is shown, which is in particular also arranged at the removal site 12. In the case of a removal, for example, the quantity removed is displayed as a number of pieces. For example, a notification can be output in case of a deviation of a maximum or minimum fill level value, and an automatic repeat order or text message can be output based on the notification, for example.

LIST OF REFERENCE NUMERALS

[0096] 1 Storage arrangement [0097] 2 Rotary storage [0098] 3 Input device [0099] 4 Depot storage unit [0100] 5 Further depot storage unit [0101] 6 Base frame [0102] 6a Upper interface [0103] 6b Lower interface [0104] 7 Rotary table [0105] 7a Base plate [0106] 7b Rim portion [0107] 8 Receiving boxes [0108] 9 Stand [0109] 10 Casing [0110] 11 Removal opening [0111] 12 Removal site [0112] 13 Drive device [0113] 14 Engine [0114] 15 Transmission device [0115] 16 Lifting device [0116] 17 Adjustment actuator [0117] 18 Lever arm [0118] 19 Support portion [0119] 20 Support pins [0120] 21 Sensor device [0121] 22 Further sensor device [0122] 23 Rollers [0123] 24 Evaluation device [0124] 25 Lighting device [0125] 26 Toothing [0126] 27 Receiving openings [0127] D Axis of rotation [0128] E1-5 first to fifth story [0129] F1 First window portion [0130] F2 Second window portion O1-5 First to fifth option button [0131] K Circle segments [0132] T1-4 Rotary storage