EP3679531A1 - Installation de production et procédé de commande de production pour la commande d'une installation de production - Google Patents

Installation de production et procédé de commande de production pour la commande d'une installation de production

Info

Publication number
EP3679531A1
EP3679531A1 EP18750419.6A EP18750419A EP3679531A1 EP 3679531 A1 EP3679531 A1 EP 3679531A1 EP 18750419 A EP18750419 A EP 18750419A EP 3679531 A1 EP3679531 A1 EP 3679531A1
Authority
EP
European Patent Office
Prior art keywords
production
loading
carrier
production plant
unit
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP18750419.6A
Other languages
German (de)
English (en)
Inventor
Manuel Kiefer
Benjamin Schwarz
Dennis Specht
Eberhard Wahl
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Trumpf Werkzeugmaschinen SE and Co KG
Original Assignee
Trumpf Werkzeugmaschinen SE and Co KG
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Trumpf Werkzeugmaschinen SE and Co KG filed Critical Trumpf Werkzeugmaschinen SE and Co KG
Publication of EP3679531A1 publication Critical patent/EP3679531A1/fr
Pending legal-status Critical Current

Links

Classifications

    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B19/00Programme-control systems
    • G05B19/02Programme-control systems electric
    • G05B19/418Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM]
    • G05B19/41865Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM] characterised by job scheduling, process planning, material flow
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06QINFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
    • G06Q10/00Administration; Management
    • G06Q10/08Logistics, e.g. warehousing, loading or distribution; Inventory or stock management
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G65/00Loading or unloading
    • B65G65/005Control arrangements
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S5/00Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations
    • G01S5/02Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations using radio waves
    • G01S5/04Position of source determined by a plurality of spaced direction-finders
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B19/00Programme-control systems
    • G05B19/02Programme-control systems electric
    • G05B19/418Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM]
    • G05B19/4183Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM] characterised by data acquisition, e.g. workpiece identification
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06QINFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
    • G06Q10/00Administration; Management
    • G06Q10/08Logistics, e.g. warehousing, loading or distribution; Inventory or stock management
    • G06Q10/087Inventory or stock management, e.g. order filling, procurement or balancing against orders
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T7/00Image analysis
    • G06T7/0002Inspection of images, e.g. flaw detection
    • G06T7/0004Industrial image inspection

Definitions

  • the invention relates to a production plant with a loading zone for loading and / or unloading at least one collecting carrier.
  • a production plant usually production orders are processed.
  • a production order may correspond to the production order to produce one or more specific workpieces of the same shape and type in a predetermined number.
  • materials required for production are provided in collecting carriers.
  • workpiece collection carriers produced workpieces are collected for removal, in particular for removal.
  • a predefined production program For the execution of a production order, a predefined production program is usually to be implemented on the production plant. Different production orders, for example for individualized small orders, often require different production programs.
  • any required materials, tools and / or the like may be provided in the loading zone.
  • suitable collective supports must be provided.
  • the collective carrier must have at least a sufficient open space for receiving the workpieces.
  • a material logistics system for coordinating the transfer of production material is disclosed, for example, in WO 2016/082883 Al. It is therefore an object of the invention to provide a production plant and a production control process by means of which the processing of production orders, in particular pre- and post-processing tasks, can be simplified, made more cost-effective and easier to automate.
  • the task is thus solved by a production plant, whereby the production plant has the following:
  • a location system for locating a collection carrier in the loading zone, wherein the positioning system is arranged to determine the position of a mobile unit arranged on the collective carrier and / or to detect identification information stored on the mobile unit,
  • an image acquisition unit configured to acquire image information of the charging zone
  • an image evaluation unit which is set up, using the image information, to determine the position of the collective carrier and / or a state of the collective carrier.
  • the positioning system can be set up to detect the position and the identification information. Based on Identification information can be identified, the mobile unit and thus the associated collective carrier. The mobile unit can thus form an (possibly indoor) tracking tag.
  • the location and / or the state of the Sammeltaines can be determined.
  • information is available that could not be obtained by the positioning system alone or only with great effort.
  • This information can be used to facilitate the preparation and / or follow-up of a production order.
  • the search effort for a production order can be reduced by deriving identification information for identifying the collective carrier required for the production order from production order data. It can then be checked on the basis of the identification numbers and on the basis of whether the required for the production order bus carrier with z. B. the necessary materials and / or tools are available and / or if necessary required collective carrier, in particular workpiece-collecting carrier, are available or to order.
  • the loading and / or unloading of the collective carrier can also be further facilitated and improved if information about the state of the collective carrier is used.
  • the mobile unit can have a memory unit in which the identification information, in particular a unique identification number and, for example, predefined order information, can be stored and read out from the location system.
  • the identification information in particular a unique identification number and, for example, predefined order information
  • the production plant can also have a production area.
  • the production area can have one or more processing machines and / or manual workplaces.
  • the loading zone can be designated as a separate area.
  • driveways and / or free spaces adjacent to production areas, in particular between individual production areas may be provided as loading zones, for example. Consequently, it is conceivable to subsume under Ladezone any places where a collective carrier can be and / or for the detection of the position and / or the position and / or the state of the Sammellies is desired.
  • a collective carrier may in particular be or have a workpiece collective carrier. It may for example be designed as a pallet or as a basket or have such.
  • the image recording unit can be designed differently.
  • the image recording unit can be designed in particular as a camera.
  • a camera can be easily installed at the production plant or in its vicinity and the image information can be evaluated directly.
  • production facilities can also be retrofitted with such an image acquisition unit and with such a location system.
  • the camera can be fixed or mobile. It can also be used for other tasks such as loading and unloading or for security purposes
  • the image acquisition unit can also be in the form of an ultrasound sensor, in particular with an additional sound source.
  • the image information does not always have to be too detailed. Under certain circumstances, very roughly screened image information may also be sufficient to detect a collective carrier.
  • the image acquisition unit may include pressure sensors and / or a light barrier network on the charging zone, e.g. at a distance of 5 to 25 cm. If the image evaluation unit is aware that only a few standardized collective carriers with known dimensions are even arranged on the loading zone, then a coarse screening suffices.
  • the image acquisition unit can also consist of receiver units that are designed to receive additional information that the mobile units transmit to the receiver units (eg via sound, light, in particular IR, Bluetooth, RFID, NFC or similar communication interfaces). With this information, the image recording unit can recognize which collective carriers, in particular in which position, are distributed on the loading zone. The image evaluation unit then associates this information with the knowledge of the collection container dimensions and thus determines the location of the collective carrier and / or its state.
  • an imaging unit in the sense of the present invention is to be understood as a recording unit which is designed to record information in interaction with the image evaluation unit a), which are sufficient to detect the position of the collecting carrier in the loading zone and / or b) to detect the state of a collecting carrier in the loading zone.
  • an imaging unit is to be understood as a recording unit which is designed, in conjunction with the image evaluation unit a), to create an image of the loading zone which is sufficient to detect the position of the collective carrier in the loading zone and / or b) the condition to capture a Sammellies in the loading zone.
  • the positioning system can also be set up to detect a predefined error and / or absence information as the position of this collective carrier.
  • the location system is designed as a radio location system or includes such.
  • it may be designed as an indoor radio location system.
  • a radio location system can detect several mobile units virtually at the same time, locate them spatially high and identify and / or distinguish them. It can cost-effectively cover large areas or large rooms.
  • the location of the mobile unit can be non-contact and not perceptible to a working person perceptible. Thus, for example, the worker is not unnecessarily distracted from their work activities.
  • the mobile unit can be set up to reflect and / or transmit radio signals adapted to the positioning system.
  • the location system can have at least one transmitting and / or receiving unit, which is preferably set up to receive these signals and evaluate.
  • the location system in particular the transmitting and / or receiving unit, may have one or more antennas. These can be spatially distributed in order to achieve particularly reliable monitoring of the loading zone.
  • the production facility has at least three transmitting and / or receiving units in order to localize the mobile unit by triangulation.
  • the location system can be designed as an ultra-wideband measuring system.
  • An ultra-wideband measurement system can operate with a comparatively low transmission power.
  • the location system in particular the ultra-wideband measurement system, can determine the position by trilateralization and / or by triangulation.
  • one or more, in particular previously known, position information about the transmitting and / or receiving units of the positioning system can be used as the starting basis.
  • the location system may be arranged to detect the position of the collective carrier with an accuracy of less than 1 m, preferably less than 0.3 m.
  • the positioning system emits, receives and / or processes signals with a particularly wide frequency spectrum, preferably in the one to two-digit gigahertz range.
  • the signals can thus have particularly steep edges.
  • the position can be determined very precisely. It has been shown in practice that, for example, the search effort mentioned at the outset can be particularly reduced with such precision. For example, it is not only possible to determine whether the collective carrier is in the loading zone, but also where it is located in the loading zone.
  • the image evaluation unit is designed, as the state of the collective carrier an actual loading state, a loading degree, an availability, a non-availability, a position, a position of an open space and / or a location of a free space of the Sammelismes to determine.
  • the actual consulting state it can thus be determined whether or how the collective carrier is loaded. For example, it can be determined whether, and if so where, on the collective carrier is still a sufficient open space for receiving workpieces to be produced available. For example, it can also be determined whether the collecting carrier is already completely filled.
  • the production facility has a loading device for loading and / or unloading the collecting carrier.
  • the loading device can be designed in particular for automated or at least partially automated loading and / or unloading of the collecting carrier.
  • the loading device can be set up to carry out a loading and / or unloading operation as a function of the position and / or the state of the collecting carrier.
  • a produced workpiece or other material to be deposited on the collective carrier can be controlled as a function of the position, the position, in particular the orientation, of the collective carrier and / or the position and / or position of an open area on the collective carrier.
  • the loading and / or unloading process can thus be carried out particularly reliably.
  • the collective carrier can also be loaded particularly efficiently, since, for example, several workpieces can be arranged particularly tightly packed.
  • the production facility has a display and control unit, preferably with a touch display unit.
  • the worker can be informed about an upcoming vacation. transfer order.
  • the worker can enter necessary data via the display and operating unit, for example data necessary for order processing.
  • the data can then be used subsequently for production control.
  • the production facility has a central production management system.
  • the production plant can also be part of a larger production unit, in which case this production unit has a central production management system.
  • the central production management system can be designed, for example, as a management execution system (MES) or have such a system.
  • MES management execution system
  • the production plant can exchange information with the central production management system or store and / or retrieve information therefrom.
  • the production plant can receive information about a production order to be processed.
  • the production facility can transmit determined information, for example, to the location, location and / or status of the collective carrier, or the success of a manufacturing step to the central production management system.
  • the collective carrier can be managed, for example, across multiple production facilities.
  • the production plant has a sheet metal processing plant or is designed as such. Frequently, orders are processed on sheet metal processing systems with a large number of order types, for example in the form of single and / or small orders.
  • the above-mentioned expense for preliminary and / or post-processing is thus particularly serious in sheet metal processing plants, so that the advantages of the production plant according to the invention are particularly prominent.
  • the scope of the invention also includes a production control method for controlling a production plant, in particular a production plant according to the invention, comprising the steps:
  • a further method step (s) may be performed.
  • the method steps (A) and (B) can be carried out simultaneously or in any order.
  • the positions of the collecting carrier, in particular within the loading zone can be determined. Based on the identification information, the collective carrier can be identified. In addition, further information, in particular regarding the position and / or the status of the collective carrier, can be recorded. Thus, for example, a missing for a production order collective carrier can be determined and ordered or requested. An already filled, for example, collective carrier can be eliminated, for example, be transported to a next processing station. The collective carrier can also be loaded and / or unloaded. In this case, according to the invention, the ordering, elimination, loading and / or unloading takes place as a function of the detected position and / or the acquired identification information.
  • the collective carrier can be loaded on the basis of the knowledge of its location and its state pinpoint and particularly efficient. In particular, the loading device can accurately arrange workpieces arranged in a space-saving manner on an open space of the collecting carrier.
  • both the position and the identification information are detected by means of the location system. This ensures that the collective carrier is clearly identified.
  • the location system can be a particularly precise location.
  • the information obtained optically by the image acquisition unit and the image evaluation unit can supplement or complete the information that can be determined by the location system.
  • the positioning system is not optical, but is designed, for example, as a radio location system.
  • Previously common manual inputs, z. B. to location and location of a Sammelmons in the loading zone, can be omitted.
  • an ACTUAL loading state a loading level, an availability, an unavailability, a position, a position of an open area and / or a position of a free space of the collective carrier is determined as the state.
  • the state can be determined, for example, whether the collecting carrier is already completely filled and / or eliminated, in particular transported away.
  • a loading and / or unloading sequence is automatically selected and / or adapted.
  • one or more control programs in a storage unit of the production facility to be stored.
  • the one or more control programs can then be retrieved depending on the actual loading state.
  • the control programs can be designed, for example, depending on the type of production order. You can, for example, provide that certain workpieces spent at certain points, especially free spaces, the Sammeltaines, in particular be discontinued.
  • the loading and / or unloading process is adapted to the extent that a collective carrier is automatically ordered and / or eliminated from the production plant.
  • the information obtained in steps (A) and / or (B) can be compared with requirements of the order, in particular with identification information of required collective carriers, their position, their position and / or their condition. For example, it can be checked beforehand whether all required collecting carriers are available in the loading zone, for example if all required materials and tools are available and / or if sufficient free space is available in one or more collective carriers for the workpieces to be produced in the collecting carrier (s) store.
  • step (C) information on the order, excretion, loading and / or unloading of the collective carrier according to step (C) is transmitted to and / or received by a central production management system.
  • a central production management system For example, the success and / or non-success of a work step, determined information such as the position of the collective carrier, its location and / or its state a production order and / or a collective carrier, in particular a manufacturing assigned to the collective carrier in the central production management system.
  • the execution of the production order can thus be monitored and / or controlled over several production plants, for example within a larger production unit and / or even over a plurality of optionally widely spaced premises.
  • the central production management system as part of a virtual data center, for example a cloud, d. H. a cloud-based data center, and is preferably arranged and / or formed in a data center available via a data interface.
  • Computing services required for the administration can thus be dynamically adapted to respective current requirements.
  • Networking of the information provided with other parties involved in the handling and / or use of the production order can be facilitated.
  • Previously unavailable or very difficult to obtain production process information can thus be made available to the parties and used by them for further, holistic cost and / or time reduction.
  • FIG. 1 is a schematic representation of a production plant
  • FIG. 2 is a schematic representation of the method according to the invention.
  • the production plant 10 is designed as a production cell in this exemplary embodiment. It has a loading zone 12, to which a production area 14 adjoins. In the loading zone 12 is a collective carrier 16.
  • the collective carrier 16 is a pallet in this embodiment.
  • a mobile unit 18 is fixed. By determining the position of the mobile unit 18, the position of the collecting carrier 16 can thus be determined.
  • a loading device 22 is provided for loading and / or unloading the collecting carrier 16 with workpieces 20.
  • the loading device 22 is in particular configured to displace workpieces 20 from the collective carrier 16 into the production area 14 and to displace workpieces 20 therefrom into the loading zone 12 and here in particular into the collective carrier 16.
  • a location system 24 has several, in Fig. 1, two transmitting and receiving units.
  • the location system 24 is set up to locate mobile units of the type of the mobile unit 18, in particular their position. auxiliaries. Thus, by locating the mobile unit 18, it can determine the position of the manifold 16.
  • the location system is designed as a radio location system, in particular as an ultra-wideband measurement system. Due to the configuration as an ultra-wideband measurement system, the positioning system 24 is able to locate the mobile unit 18 or its associated collective carrier 16 with a spatial resolution of less than 30 cm.
  • an image acquisition unit 26 to which an image evaluation unit 28 is connected, forms part of the production facility 10.
  • the image acquisition unit 26 is designed as a CCD camera. For simplicity, only one image pickup unit 26 is shown in FIG. It is also possible to provide a plurality of image recording units 26. In particular, it can be ensured by a plurality of image recording units 26 that the loading zone 12 is completely optically detected and, in particular, obstacles in the field of view of an image recording unit 26 can be compensated by means of the field of view or image of another image recording unit 26.
  • the image pickup unit 26 and the image evaluation unit 28 are arranged together to optically monitor the loading zone 12.
  • the image acquisition unit 26 and the image evaluation unit 28 are set up to determine the position and an actual loading state of the collecting carrier 16.
  • the image evaluation unit 28 is designed as part of a computer unit designed as a control unit 30.
  • the location system 24 and, via the image evaluation unit 28, the image acquisition unit 26 are also connected to the control unit 30 for data processing purposes.
  • both the information of the location system 24 and the optical information of the image acquisition unit 26 or of the information obtained therefrom by the image evaluation unit 28, in particular the position and the state of the collective carrier 16, are available.
  • the collective carrier 16 has an open space 40, which is recognized by the image evaluation unit 28 as such. Via the control unit 30, this information is combined on the basis of identification information 42 of the mobile unit 18 with the information provided by the positioning system 24 to the position of the manifold 16.
  • the mobile unit 18 has a memory unit, in which the identification information 42, in particular a unique identification number and, for example, predefined order information, can be stored and read out therefrom by the location system 24.
  • This identification information 42 is additionally printed on the mobile unit 18 in a readable manner for a worker in this exemplary embodiment.
  • the location system 24 is designed to also read out this identification information 42 from the mobile unit 18 or to interrogate and receive it from the mobile unit 18.
  • the display and control unit 32 has a touch display unit. It is used to display production information for a worker and to enter additional data required for a production order by the worker.
  • the control unit 30 is also connected via a data interface 34, in this embodiment a data network, in particular a WAN (Wide Area Network), to a central production management system 36. connected.
  • the central production management system 36 is part of a virtual data center, in particular a cloud 38.
  • At least one computer program product is executably stored on the central production management system. This is executed in operation in the cloud 38.
  • the computer program product is designed to manage and monitor several, in particular all, production orders to be processed.
  • one or more control programs specifically tailored to different production orders or order types are stored, in particular for optimized control of loading and unloading processes, as explained in more detail below.
  • FIG. 2 schematically illustrates a production control method 100 for controlling a production plant, which will be explained in more detail below.
  • a production control method 100 for controlling a production plant, which will be explained in more detail below.
  • it is provided to control a production plant corresponding to the production plant 10 according to FIG. 1.
  • a first step 110 first the production plant 10 and the collective carrier 16 are prepared.
  • the mobile unit 18 is assigned a unique identification information 42, in particular an identification number, and stored in this retrievable manner.
  • the manifold 16 is uniquely identifiable.
  • this identification information 42 may additionally be printed or displayed on the mobile unit 18.
  • this identification information 42 and at least for one production order all information necessary for this production order is deposited.
  • the central production management system 36 selects a production order to be processed and transmits to the control unit 30 via the data interface 34 the associated order data, in particular identification numbers of the collection carrier 16 required for order processing or of the mobile units 18 associated therewith
  • the central production management system 36 also transmits one or more specific control programs to the control unit 30 in which, in particular, an optimized loading and / or unloading sequence or strategy for production order-specific control of the loading device 22 is coded.
  • the control unit 30 provides this information by means of the output and control unit 32 of a worker for information and control. The worker then starts the execution of the production order by pressing the output and control unit 32nd
  • a step 114 on the basis of this information, it is checked whether all the collective carriers 16 required for the production order, in this example thus the collective carrier 16, are located in the loading zone 12. For this purpose, the determined identification information is compared with the identification information stored in the production order.
  • Missing the collective carrier 16 (in Fig. 2 with minus marked path), so this is ordered in a step 116 and provided in the loading zone 12 and possibly determined its position again.
  • the provision can be made by the worker or - in a variant of the method - for example by means of an automatic transport system, which is advantageously controlled by the control unit 30.
  • the position of the collecting carrier 16 and its actual loading state are determined by means of the image recording and evaluation units 26, 28. In particular, it is determined how the collective carrier 16 is aligned with respect to the loading zone 12 and where on the collective carrier required materials and workpieces to be machined 20 are stored.
  • a suitable control program in particular a discharge program, is selected on the control unit 30 or - in a variant of the method - transmitted from the central production management system 36 to the control unit via the data interface 34 and executed on the control unit 30.
  • a specific to the production order and to the collective carrier 36 tuned unloading, so that the loader 22 all the elements required for the production, especially the workpieces 20, fits precisely and transported on optimized transport routes targeted from the collective carrier 16 to the production area 14 and thus discharges the collective carrier the production order with minimal time.
  • Each individual transport of a workpiece 20 is reported by the control unit 30 via the data interface 34 to the central production management system 36 and logged by this in this.
  • step 120 the workpieces 20 are processed in the production area 14 according to the order.
  • the collecting carrier 16 is loaded in a step 122 with the machined workpieces 20.
  • the position of the collecting carrier 16 is detected again by means of the locating system 24, and its position and its current actual loading state are determined by means of the image recording and evaluation units 26, 28.
  • the loading device 22 is then controlled by a loading program executed on the control unit 30, so that the collecting carrier 16 is loaded again with the workpieces 20. Likewise, the workpieces 20 are booked out individually in the central production management system 36.
  • the success of the processing step and the actual loading state are returned from the control unit 30 to the central production management system 36 via the data interface 34 transmitted.
  • the central production management system 36 a virtual image of the current production situation in the production plant 10 can be created.
  • the collecting carrier 16 is brought to a subsequent production facility for further processing, depending on the production order, or, for completion of the workpieces 20, for delivery to a distribution warehouse
  • the invention relates in summary to a production plant 10 and a production control method 100 for controlling a production plant, in particular a production plant 10, by or in which by means of a positioning system 24 identification information 42 and / or position and by means of a Imaging unit 26 and an image processing unit, a position and a state, in particular an actual loading state, a collection carrier 16 are detected or determined.
  • the collective carrier 16 can be ordered, loaded and / or unloaded as required for processing a production order, and removed from the production plant 10, in particular after completion of the production order. Previously necessary pre- and post-processing are thus reduced to a minimum or sometimes even avoided.
  • the production plant 10 can be particularly flexible and easily adapted even to a wide variety of production order types by the current detection of this individual information. The execution of the production order can be accelerated by eliminating previous sources of time losses. In a central production management system 36, these and other items related to the production order can be used. filed and managed centrally. The degree of automation of the production facility 10 can thus be significantly increased in a simple manner.
  • the position of the mobile unit 18 can be determined solely by an analysis unit, ie without manual interaction.
  • Previous systems for locating workpieces or jobs in manufacturing facilities have the disadvantage that lost workpieces or jobs must be searched manually. It has been recognized that these manual searches, especially in manufacturing facilities with a high number of small and constantly changing orders, ie z. As in toll manufacturing, account for a tremendous proportion of non-productive time.
  • the need for time-consuming manual searches of workpieces 20, but also of tools or persons, can thus be drastically reduced, especially in the (steel and / or sheet-metal processing) industrial production.
  • the concepts disclosed herein are based on the use of a 2D / 3D indoor (indoor) location system as a starting point for location-dependent information processing.
  • the positioning system 24, in particular the mobile units 18, can optionally be equipped with further sensors, for example with at least one acceleration and / or position sensor, and thus also serve as the basis for position-dependent information processing.
  • a location-dependent (and, if appropriate, position-dependent) interaction in the context of the 2D / 3D interior location system in the production or production tion and optimization of manufacturing processes For example, gates and zones can be used to automatically monitor and control a manufacturing process and subsequent production steps.
  • locating systems 24 in consideration of the expected process operations in a production hall is also possible in the special environment of a steel and / or sheet metal processing industrial production. Accordingly, such positioning systems can be integrated into a production control system (also referred to herein as a production control system or MES (Manufacturing Execution System)).
  • MES Manufacturing Execution System
  • the use of such location systems 24 z. B. despite the existing steel and sheet metal possible, although metallic workpieces 20 can reflect and shield the electromagnetic signals used. The use is still possible even if the metallic workpieces 20 are still moved locally and so change the reflection surfaces constantly in their position and orientation.
  • 2D / 3D indoor location systems 24 can result in complexity in the low-cost, dynamic assignment of acquired location information to physical components.
  • the concepts disclosed herein address this complexity and allow, for example, to associate production orders with associated IDs without the laborious interaction of a mobile unit 18 with which the location information to be allocated is obtained.
  • Interior location systems 24 allow the detailed mapping of material flows in production within a production hall into digital process processing. The location systems 24 thereby simplify the localization of the objects / persons participating in the production in the production environment. If tools, equipment or load carriers are initially equipped with a localizable mobile unit 18 of the location system 24, they are to be assigned manually or automatically in accordance with digital information in the digital control system. This also applies to objects that are temporarily involved in production, such as production orders or service personnel. Temporarily required dynamic allocations can arise again and again and are required only few hours, days or weeks in the production hall. In order to enable and ensure the dynamic allocation of the mobile units 18 to new production orders with little effort and reliability, the process aids proposed here can be used.
  • Indoor positioning may be reduced to less than 30 centimeters, and more preferably less than 10 centimeters, accuracy in a manufacturing hall not accessible from GPS satellite signals, having a floor plan in the range of e.g. B. 1 ha done. This accuracy is essentially impossible with other techniques (Bluetooth, WiFi, WLAN, infrared, cellular, RFID).
  • Bluetooth, WiFi, WLAN, infrared, cellular, RFID Bluetooth, infrared, cellular, RFID
  • jobs people (eg, operators) and / or tools, many requirements must be considered.
  • industrial production is increasingly geared towards the production of small batches with many individual work steps (manufacturing processes such as cutting, bending, grinding, surface treatment) at different workplaces such as machine workstations and manual workplaces. This often results in several hundred different orders in one day. who all require different work steps.
  • a real-time location is sought. It should be locally so accurate that mobile units 18 can be safely found and / or assigned to the processing steps. It has been found that a location that is accurate to only 1 m, is not enough. Also is a location, which causes any change in the radiation behavior of electro-magnetic waves, z. B. by movement of metallic workpieces 20 in the production hall, would have to be recalibrated, disadvantageous and often not applicable.
  • the location should also be flexible, multiple orders should be summarized to a job, one order should be split into several orders, etc. The location should be easy to use. It should be fail-safe. In general, the concepts disclosed herein may allow for increased process reliability, optimization of cycle times, and, correspondingly, cost optimization of production.
  • the concepts disclosed herein may be e.g. T. cause significant time savings in the manufacturing process, with the manufacturing process z. From the production of a required number of parts to the correct transfer to a subsequent process (eg, a subsequent metal working step). Several orders can also be implemented at the same time process reliable.
  • the concepts disclosed herein further allow for easy assignment of workpieces 20 as part of location system 24. Thus, open jobs can be optimized despite the complexity of multiple jobs to be processed simultaneously.
  • aspects described herein are based, in part, on the recognition that, with the accuracy and reliability of new location systems based, in particular, on the UWB technology, for example with an accuracy in the location of less than 30 cm, in particular ner 10 cm, the use of indoor location systems in the context of industrial production makes sense.
  • the positioning systems disclosed herein for integration into industrial manufacturing are based on mobile units 18 (also referred to herein as “tags”) and stationary transceivers (also referred to herein as “anchors” or “anchors”).
  • mobile units 18 also referred to herein as “tags”
  • stationary transceivers also referred to herein as “anchors” or “anchors”
  • the mobile units 18 are generally electronic components that are capable of communicating with the transceivers, particularly by means of UWB communication technology.
  • Each mobile unit can have its own time determination unit ("clock") to determine runtimes.
  • the location system 24 may include a plurality of transceiver units and at least one mobile unit 18.
  • the location system 24 may also interact with the MES.
  • an analysis unit of the location system 24 may be formed as a part of the MES.
  • the transceiver units may be configured to transmit to the mobile units 18 UWB radio signals and to receive from these UWB radio signals.
  • the distance between a locally movable mobile unit 18 and a z. B. permanently installed transceiver unit can be determined by the time that the signal to overcome the distance between the both units needed. If the distances are determined by a plurality of transceiver units, the location of each of which is known, the spatial location of the mobile unit 18 with respect to the transceiver units z. B. be determined by triangulation.
  • the transceiver and mobile unit (s) 18 may have highly accurate clocks that can accurately time the time to a few or even fractions of ns. Even if the clocks in the transceiver unit and in the mobile unit 18 are highly accurate, the clocks are not necessarily synchronized. Different methods of synchronization of clocks or the elimination of errors following from the asynchronous clock history can be used.
  • one of the transceiver units, z. B. as a master position determining unit, a signal at a first time Tl and send a second signal at a second time 12.
  • the mobile unit 18, the time difference T2-T1 be known or transmitted together with the signals, so that they on the Synchronize the time of the transceiver units.
  • the mobile unit 18 may transmit two signals at a known time interval Ta.
  • the transmitter-receiver unit can determine the synchronization deviation based on its own time measurement with its own clock from the reception of the first signal to the reception of the second signal and calculate out of the distance measurement.
  • the time interval between the first signal and the second signal should be low, so that the mobile unit 18 has not moved significantly locally during this time.
  • the time interval may be selected by the mobile unit 18 to be a predetermined multiple or predetermined fraction of the time that the mobile unit 18 requires from receiving a signal to respond to until the first signal is output.
  • the transceiver units may also be connected to the analysis unit via wireless or wired communication links.
  • the mobile units 18 may only communicate via the transceiver units. Alternatively or additionally, they can independently communicate with the analysis unit / MES via further communication connections (for example a WLAN connection).
  • further communication connections for example a WLAN connection.
  • the data communication of the transceiver units and the mobile units 18 with a production control system, in particular with the MES, may be bidirectionally possible.
  • WLAN sending stations may be integrated into the transceiver units of the location system for data access into the shop floor control system such that digital data may be mobilized via the transceiver units in the shop floor.
  • the integration of the WLAN transmitter stations in the transceiver units can simplify the installation and operation of a data communication system in the production hall.
  • the UWB technology uses frequency ranges of, for example, 3 GHz to 5 GHz, whereby the UWB technology uses a relatively large frequency range for the formation of temporally sharply defined signal paths (communication frames).
  • a signal with very steep edges That is, the signal is more likely to be a rectangular signal Run over time as a sinusoidal course. This requires a signal in which several sinusoidal signals with different frequencies are superimposed. Because of several sinusoidal signals with different frequencies, a signal can be formed, which has a steep edge and can be approximated to a substantially rectangular shape over time. This means that several frequencies from a broadband frequency spectrum must be available to form a signal.
  • UWB technology which has a broadband frequency spectrum, is particularly suitable for exact localization.
  • the technology and the usable frequency bands of the UWB technology are described, for example, in the standard "IEEE 802.15-2015".
  • an LED may be provided on the mobile unit 18. This can, for example, visually communicate information coded to humans by different colors, flashing frequencies or flashing patterns. A particular flashing LED is easier to recognize even at long distances than z. B is an ad. Therefore, a signaling device such as an LED has special advantages when z. B. a mobile unit 18 is searched. It can be addressed remotely by an operator and then become noticeable with a signaling device. Additionally or alternatively, it can emit a noise signal. Such a remote addressing can, for example, by another mobile unit 18 or via any other particular portable device, eg. As smartphone, tablet, or via the analysis unit. But you can also directly, for. B. via near field transmitter (eg., Bluetooth, NFC, IR) done.
  • near field transmitter eg., Bluetooth, NFC, IR
  • the mobile unit 18 may further comprise one or more different sensors for determining the position, the acceleration, the movement in the Room by gyrosensor, which includes temperature, magnetic field, electric field, humidity, brightness, sound, vibration, etc. These can be used for additional functions.

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Abstract

La présente invention concerne une installation de production (10) qui comprend : - une zone de chargement (12) pour charger et/ou décharger au moins un support collecteur (16), - un système de localisation (24) pour la localisation d'un support collecteur (16) dans la zone de chargement (12), le système de localisation (24) étant conçu pour déterminer la position d'une unité mobile (18) disposée au niveau du support collecteur (16) et/ou pour détecter une information d'identification (42) enregistrée sur l'unité mobile (18), - une unité de prise d'images (26) qui est conçue pour détecter des informations d'image de la zone de chargement (12), - une unité d'évaluation d'images (28) qui est conçue pour déterminer, à l'aide des informations d'image, l'orientation du support collecteur (16) et/ou un état du support collecteur (16). La présente invention concerne en outre un procédé de commande de production pour la commande d'une installation de production (10). L'installation de production (10) selon l'invention ainsi que le procédé de commande de production selon l'invention permettent un meilleur traitement d'ordres, en particulier des tâches de préparation et/ou de post-traitement sont simplifiées et peuvent être plus facilement automatisées. (Fig. 1)
EP18750419.6A 2017-09-05 2018-08-03 Installation de production et procédé de commande de production pour la commande d'une installation de production Pending EP3679531A1 (fr)

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DE102017215613.9A DE102017215613A1 (de) 2017-09-05 2017-09-05 Produktionsanlage und Produktionssteuerungsverfahren zur Steuerung einer Produktionsanlage
PCT/EP2018/071141 WO2019048149A1 (fr) 2017-09-05 2018-08-03 Installation de production et procédé de commande de production pour la commande d'une installation de production

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US11625026B2 (en) 2023-04-11
CN111183439A (zh) 2020-05-19
US20200201303A1 (en) 2020-06-25
DE102017215613A1 (de) 2019-03-07
CN111183439B (zh) 2023-12-12

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