NL1016686C2 - Identification method for physical assembly of objects, using unit having physical relationship with and receiving identification information from these objects - Google Patents

Abstract

An identification unit (10) having a physical relationship with the objects (50, 52, 54, 56) in the assembly is provided, identification information for each object is sent to the unit, and the assembly is identified on the basis of all this information. An Independent claim is also included for the identification unit, comprising a processor unit (25), a communication unit (20) and a memory (30).

Description

Title: Identification of multiple objects

The invention relates to a method for identifying a physical set according to the preamble of claim 1.

It is known from practice to provide objects, such as for example parts, with an identification means such as for example a bar-5 code or a tag with a transponder. By reading this identification means, it is possible to determine which object is concerned on the basis of the identity data included in the identification means. The identity data often refer to a certain element in a database. When a collection of objects is assembled, for instance by assembling an object that is composed of different objects or for instance by assembling a package to be sent with different objects, the identification means of each object are read.

Reading the identity data of all objects is difficult and sometimes not feasible. For example, it is often difficult to scan barcodes when the parts on which they are mounted are mounted. Transpon thirty-day working with radio detection are also difficult to read out individually if they are situated at a short distance from each other or, conversely, are situated at a large mutual distance. In addition, when reading transponders, disturbing interference often occurs due to the presence of metal parts. The invention has for its object to provide a method with which a physical collection of objects can be identified in a simple and reliable manner.

To this end, the invention provides a method according to claim 1. Because the identification data of the objects in the collection are stored in an identification unit that is physically connected to the collection, only the identification unit needs to be approached to identify the collection. As a result, no problems arise with reading closely located identification means of the objects.

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The invention further provides an identification unit that is particularly suitable for use in the method according to the invention.

Particularly advantageous embodiments of the invention are described in the dependent claims. Further aspects, effects, advantages and details of the invention are explained below with reference to an exemplary embodiment of the invention, with reference to the drawing. Fig. 1 shows an example of an identification unit according to the invention, FIG. 2 shows the identification unit of FIG. 1 provided with objects, FIG. Fig. 3 shows a transport trolley provided with an identification unit, Fig. 4 a car provided with an identification unit, Fig. 5 a system with an identification unit according to the invention, Fig. 6 a second system with an identification unit according to the invention invention, fig. 7 an example of an intermediate station according to the invention, and fig. 8 an example of a database system according to the invention.

Fig. 1 shows an example of an embodiment of the invention. An identification unit 10 according to the invention is provided with communication means 20, a processing unit 25 and a memory 30. The communication means 20 are adapted to send and receive data, and can be designed in any suitable manner. The processing unit 25 is adapted to control the functions of the identification unit 10; for example, the processing unit may be provided with a processor and a program memory containing a program executed by the processor, such as, for example, embedded software. The memory 30 is arranged for the storage of identification data.

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The identification unit 10 is connected to a physical area 40. This area 40 may, for example, be a transport means for transporting objects such as a transport trolley 200 (Fig. 3), or, for example, an object being assembled, such as a car 300 (Fig. 3). 4).

In this example, four objects 50, 52, 54, 56 are added to the area 40, as indicated by the arrows in Fig. 1. These objects are each provided with an identification means 51, 53, 55, 57, respectively. is provided with identification data with which the relevant object can be identified. The identification means can be designed in any manner thereto, for example as a barcode or transponder. The identification data may also include reference data related to a data item from a database of data relating to the objects. For example, the reference data may include a code number corresponding to a data item of a product database, the data item comprising various data about the object.

The objects 50, 52, 54, 56 may, for example, be packages that are loaded onto a transport trolley, as shown in Fig. 3. In this example, the loading of the packages onto the transport trolley is understood to mean adding the objects to the area 40 The objects can for instance also be parts that are assembled into a whole, such as for instance parts of a car, as shown in Fig. 4. In this example, the mounting of the objects on the car is understood by adding the objects to the car. area 40.

When the objects 50, 52, 54, 56 are located within the area 40, 25, the situation as shown in Fig. 2 arises, thereby forming a collection of objects. The identification data of the respective identification means 51, 53, 55, 57 is then transferred to the identification unit 10, where this data is stored in the memory 30. According to the invention, the identification data can be stored in any suitable manner. transferred to the memory; A few examples of this data transfer will be described below.

In order to subsequently determine which objects are present in the area 40, contact can be made by means of a communication device 100 with the identification unit 10. Via the communication means 20, the identification unit 10 can then be used in the memory 30 pass on stored identification data. This achieves that the identity data of the objects in a physical set can be determined in a quick and simple manner by communication with a single identification unit. This avoids that for determining the identity of each object the identification means of each object must be determined separately. According to the invention, data can be read from the identification unit at any desired time. For example, during an assembly or assembly process, the composition of the assembled or assembled can be determined at any desired moment. In such processes, the set changes over time, and the invention has the advantage that the changing composition of the set can be followed. In applications where the composition of a collection does not change, but the position of the collection does, for example during transport and storage, the identity of the objects in the collection can be determined at any desired moment according to the invention.

In the following, some exemplary embodiments for data transfer between the objects and the identification unit are described.

Fig. 5 shows an exemplary embodiment according to the invention in which the identification unit 10 is embodied such that the communication means 20 can directly read the identification means of the objects 50 ... 56 (indicated by the arrows A and A 'in Fig. 5 ), and can store the identification data directly in the memory 30. For example, the communication means may be provided with a transponder reader if the objects are provided with transponder tags or, for example, with a barcode reader if the objects are provided with a barcode. The identification unit can be designed to read the identification means of the objects at the moment that the objects enter the area 40, such as, for example, on a transport trolley 200 on which the identification unit is arranged. The advantage of this is that no additional actions are required. Transponders can advantageously be used in this exemplary embodiment. The identification unit may alternatively be embodied such that an object which is added to the set in the area 40 must first be registered or registered by means of the communication means. For example, the person adding the object to the set can first register the object to the identification unit, for example by having a barcode scanned on the object by the communication means.

In an embodiment variant according to the invention the identification means of the objects are read by the identification unit, whereafter the identification unit makes contact via the communication means with a database and reads further data associated with the objects from the data base and reads it into the database. store memory. This has the advantage that a large amount of data per object can be stored, while the information density of the identification means on the objects can be low.

Fig. 6 shows an embodiment according to the invention in which the identification means of the objects which are added to the set need not be read by the identification unit 10. The data relating to objects added to the set are obtained by means of an intermediate station 400, indicated by the arrows B and B 'in Fig. 6, and then transmitted to the identification unit 10, indicated by the arrow C. intermediate station 400 is preferably equipped with a reading device adapted for reading the identification means of the objects, such as for example a barcode reader or a transponder reader. The person bringing the objects within the area 40, for example during the leave of a transport vehicle 200, or the assembly of a car 300, reads the identity data of the added objects by means of the intermediate station 400. Subsequently, the data is passed from the intermediate station 400 to the identification unit 10. The intermediate station 400 can consist of various individual components which are communicatively connected to each other. Fig. 7 shows an example of an intermediate station 400, comprising a barcode reader pen 410. With this reader pen 410, a person scans added to the collection of added objects which are provided with an identification means in the form of a barcode. Subsequently, the data obtained by means of the reading pen is transmitted by means of the communicative connection 415, for example an infra-red communication connection known as such, to a computer system 420, which transmits the identification data via an interface 430, for example wirelessly by means of radio waves. identification unit 10. To this end, the communication means 20 of the unit 10 are adapted to receive radio signals.

According to the invention, the transfer of the identification data of the objects added to the set can take place immediately after the addition of a single object, for example in real time. In addition, the identification data of the objects added to the set can be transferred after a number of objects have been added, for example after completing a process step, for example when a transport trolley 200 is completely filled, or when the assembly of a car 300 is completed. is complete. This has the advantage that the data traffic remains limited.

If the identification unit 10 is provided with data from the objects belonging to the unit 10, the entire set as described above can be easily identified. The set associated with the identification unit 10 can then be used as a unit in a product tracking system known per se. It is advantageous here that the identification data of the objects are stored in the memory of the unit 10, as a result of which the unit 10 can execute the identity of the relevant objects autonomously, and in particular without communication from a database.

In an embodiment variant according to the invention, the identification unit 10 is provided with a location-determining device, such as, for example, a GPS module (Global Position System), with which the identification unit 10 can determine its position. The unit 10 can communicate its position in communication by means of the communication means 20. This has the effect that the tracing of the unit 10 becomes considerably simpler and more accurate.

Fig. 8 shows a database system 500; this database system is adapted to process data from a number of identification units 10. For this purpose, the database system 500 is provided with communication means, which can make connections D and D 'between the system 500 and the units 10. Such database systems are from the known in practice and are used for, among other things, controlling and controlling logistical processes, such as transport, logistics and goods flows during manufacture. The database system 500 is arranged such that data can be transmitted to the units 10, while the units 10 are designed such that they can transmit data to the database system 500, such as, for example, positional data. Because data exchange between the database system 500 and the units 10 is possible, the quality of the data in the database is improved.

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Claims (9)

Method for identifying a physical set of objects, comprising the steps of each object provided with an identification means comprising object identification data, characterized by providing an identification unit that is in physical relation to the set of objects, transferring it to the identification unit of the object identification data of each object belonging to the set, and identifying the physical set by means of the identification unit. 2. Method as claimed in claim 1, wherein the transfer to the identification unit of the object identification data of each object belonging to the set takes place by reading the object identification data of each object by the identification unit. The method of claim 1, wherein the transfer to the identification unit of the object identification data of each object belonging to the set takes place by reading the object identification data of each object by means of an intermediate station. A method according to any one of the preceding claims, wherein transferring to the identification unit the object identification data from each object belonging to the set takes place immediately after an object is added to the set. 5. Method as claimed in any of the foregoing claims, wherein the transfer to the identification unit of the object identification data of each object belonging to the collection takes place after a certain amount of objects has been added to the collection. ito 1 6; 6. Method as claimed in any of the foregoing claims, wherein transferring to the identification unit of the object identification data of each object belonging to the set comprises transferring information belonging to an object to the identification unit from a database. A method according to any one of the preceding claims, wherein identifying the set comprises performing object identification data stored in the identification unit of each object belonging to the set, by the identification unit. An identification device comprising a processing unit (25), a communication unit (20), and a memory (30) for use in a method according to claims 1-7. The identification device according to claim 8, further comprising a device for determining the location of the identification device. f 1 1 6 68 6