AT15635U1 - Bridging device for a housing of a collection - Google Patents

Abstract

The invention relates to a bridging device (13) for a housing (9) of an object group (2) which has a plurality of monitoring objects (1) each provided with non-contact readable identification elements (3) having a unique identifier, the housing ( 9) has a shielding effect. So that monitoring objects (1), which are arranged in a shielded housing (9) of an object group (2), are detected by scanning an external antenna from the detection devices of a system, the bridging device (13) according to the invention comprises an internal antenna (10), an external antenna (11), and a gateway (12), which enable detection of arranged in the housing (9) labeling elements (3) via the outer antenna (11).

Description

description

BRIDGE DEVICE FOR A HOUSING OF AN OBJECT GROUP

The subject description discloses in a first aspect a system for detecting a stock of monitoring objects of a plant having a plurality of fixed or non-fixed areas where monitoring objects may be located, the plant being adapted to perform operations using the monitored objects ,

In a second aspect, the description discloses a method for mapping an inventory of surveillance objects of a facility in an inventory database, the facility having a plurality of detection devices, each associated with a portion of the facility, and wherein the surveillance objects include identification elements preferably be read by the detection devices without contact.

Finally, the invention relates to a bridging device for a housing of a group of objects, which has a plurality of monitoring objects, which are each provided with non-contact readable identification elements (RFID tag) having a unique identifier, wherein the housing has a shielding effect.

Numerous solutions have been created for the tracking of moving or non-stationary objects, in particular GPS-based solutions, for example for the tracking of vehicles or mobile devices, or RFID-based tracking systems are used. Tracking systems based on satellite navigation, in particular GPS, have the disadvantage that they are not suitable for systems inside buildings because the satellite connection is disturbed here. RFID systems are used in particular for warehouses for automated warehouse management, all goods in the warehouse are provided with an RFID tag, which is scanned when storing and retrieving the goods with either a handheld scanner or a built-in scanner, so that a stock movement detected automatically and can be maintained in the system.

US2010 / 0156597 A1 discloses such an inventory system for products provided with an RFID tag in a shop or warehouse whose inventory is detected using RFID readers.

US 2004/0024644 A1 discloses an RFID-based monitoring system for goods in a logistics process.

For the automatic monitoring of surveillance objects in dynamic changing environments, as prevalent in test environments such as engine test benches, the prior art systems are poorly suited. This is partly because the known systems do not provide a hierarchical structure of the monitored objects. Thus, it can be determined with existing systems, whether a particular object (ie a tagged with an RFID tag object) is currently in the system, but it can only be made statements about the exact position and it is not known whether the Item is combined with other items to form a functional group. Therefore, it is also not possible to identify exactly using an automatically maintained database, for example, if a test run planned at a test facility can be performed with the just installed monitoring objects.

It is an object of the present invention to provide apparatus and methods that greatly facilitate the planning, feasibility study, and performance of dynamic and variable equipment, and in particular, to facilitate the design and performance of test (e.g., test run) test rigs.

Accordingly, these objects are achieved with a system mentioned above, in which the Anlaqe has a plurality of detection devices, which are each assigned to a portion of the system, the monitoring objects are each provided with preferably non-contact readable label elements having a unique identifier wherein the detection devices have a data connection to a computing unit that manages an inventory database. This system enables automated management and monitoring of the monitoring objects of a plant, whereby also the status of the plant, i. the respective configuration can be determined at any time.

In the context of this description are referred to as "monitoring objects" all existing in the system objects that are provided with a readable label element, in particular an RFID tag, which carries a unique identifier. In particular, surveillance objects may be devices (e.g., gauges, transport devices, objects to be tested, etc.) or (raw) materials used in the plant. (Since many consumables themselves can not be provided with an RFID tag, in particular, the containers for consumables such as refill containers such as cartridges for lubricants, toner containers, tanks, or the like can be defined as monitoring objects). For test environments, the particular arrangement and combination of currently installed measuring devices is of particular interest.

In the context of the present description, "areas" are spatially delimited locations at which monitoring objects can be located. As an area, for example, a particular space, work area or machine may be defined without being limited thereto. Advantageously, the detection of the monitoring objects also allows a statement as to whether the corresponding monitoring object is in a usable position, e.g. whether a measuring sensor is inserted in the receptacle provided for this purpose.

In connection with the subject description, an "identification element" is preferably an object which can be localized without contact by a detection device, e.g. an RFID tag, wherein the object has a readable unique identifier, in particular a code that allows an unambiguous assignment to a particular monitoring object. The code may e.g. be associated with a serial number of the object. Depending on the purpose, it is also possible to use tactile (for example in the form of a chip card) or optically (for example as barcode) readable identification elements or a combination of different identification elements.

The performed by the plant workflow can be in particular a production process or a test method. Especially in test environments, it is important to have an overview of the existing meters in the test bench (e.g., for flow, emission, particle count, power, etc.) always up to date.

Furthermore, the system may comprise at least one detection device or a group of detection devices, which is / are suitable for determining the position. As a result, not only the presence, but also a current position of monitoring objects can be recorded in order to be able to find the respective devices with the system during operation and replace them if necessary. In general, objects that are needed, for example, for a measuring task, such as a measuring shaft, certain hose connections, adapters for mechanical connections, actuators such as driving lever adjuster, etc., can be marked and inventoried in this way.

Advantageously, the system may comprise a plurality of object groups, which may comprise one or more monitoring objects. This allows the formation of complex functional units, which can be detected as a whole or on the basis of individual monitoring objects.

As "object group" is in the context of the present description, a monitored, possibly not fixed unit, referred to, which comprises a plurality of monitoring objects. An object group can be assigned certain functions that depend on the status of the monitoring objects in the object group and / or the location of the object

Object group can be dependent. For example, gauges may be defined as a collection consisting of parts or subsystems, e.g. Sample aspiration, sample preparation, measuring sensor, evaluation electronics, or similar. If necessary, such parts or modules can also be exchanged individually.

By monitoring the object groups can be ensured that always a consistent set of approved parts is used.

In a preferred embodiment, the arithmetic unit may have means to check whether a given workflow of the system with the existing monitoring objects or object groups can be performed. This creates the possibility of an integrity check of object groups and a forward-looking resource planning.

As "integrity check" is referred to in the context of the subject description, a method in which it is checked whether an object group contains all monitoring objects that are required for the execution of a particular task, if necessary, if all object groups or monitoring objects are present and / or are within a predetermined range, if applicable, whether an object group or monitoring objects contained therein are operational, or require maintenance, and if so, whether specific or all monitoring objects and / or object groups are original products. This also allows detection of product counterfeiting.

Advantageously, the plant may be part of an intelligent manufacturing line, and the workflow may be a production process. This allows predictive simulation and planning of set-up times, production processes and service activities. An "intelligent production line" is an arrangement of machines, raw materials and control devices, which allows automated adaptation of the system to different production processes.

In a further advantageous embodiment, the system may be part of a test environment, and the workflow may serve to perform a test, an experiment and / or a measurement method. This allows a minimization of the preparation and set-up time for the execution of a test run.

A "test environment" is a system which has at least one test stand and in general a multiplicity of measuring devices. The test track may also have an integrated simulation environment, e.g. for performing a HiL simulation. The workflow performed by a test environment, where a test bench is operated under certain parameter specifications, generally serves to perform different measurements.

In the second aspect of the present description, the objects are achieved by a method mentioned above, comprising the following steps: By means of a detection device associated with a range reading at least one unique identifier from at least one contactless readable identification element, which is present in the corresponding area is; Determining a particular monitor object associated with the identifier read from the identifier; Determining data concerning the monitoring object; and storing or updating the data in the inventory database. With this method, an up-to-date display of the monitoring objects actually present in the plant can be automated. In this case, a spatial assignment of the monitoring objects to each area is possible. For example, monitoring the feasibility of certain tests allows planning which tests (e.g., test runs) on which test benches can be performed on specific dates (scheduling). It can also be determined which measuring devices are required for this. By detecting the devices present on the test bench, it is now possible to automatically display whether these tasks can be carried out as planned. Furthermore, a warning can be automatically generated if e.g. a soon to be required device by the operator accidentally removed from a test bed. In an advantageous manner, the method may further comprise the following steps: determining an object group to which a specific monitoring object is assigned; Determining data pertaining to the collection; and storing or updating the data in the inventory database. By marking several parts of a device (for example measuring sensor, conditioning unit, signal processing, control panel) with one RFID tag each, the consistency can be checked from the combination in addition to the simple presence of the entire system (= device), ie. For example, it can be detected whether a specific part, for example a conditioning unit, has been changed since the last detection (and thus another ID is reported by the RFID tag). This can be used to automatically notify about any previous maintenance activities, conversions, and possibly the presence of counterfeiting.

Advantageously, the reading can be timed and / or triggered when an event occurs. As a result, both ongoing monitoring (for example, to detect when a surveillance object enters / leaves an area) and detection of an overall image at a particular point in time are possible.

Furthermore, the method can advantageously have the step of checking the integrity of a monitoring object and / or a group of objects. Thus, the completeness and readiness of the system can be queried.

Advantageously, it can also be checked whether an activity planned on the system can be carried out with the monitoring objects or object groups present in the system. If necessary, a warning can also be issued. This avoids configuration errors in a timely manner.

In an advantageous embodiment, data of the database can be transmitted to a non-plant service provider. This allows remote monitoring and maintenance planning by a service provider, e.g. by the manufacturer of the plant. The owner may determine which data should be transmitted to the service provider and which should not (e.g., only consistency data). This allows the provision of a central inventory management.

The aforementioned bridging device according to the invention comprises an inner antenna, an outer antenna, and a gateway, which allow detection of arranged in the housing identification elements via the outer antenna. By means of this device, also monitoring objects which are arranged in a screened housing of a group of objects can be detected by scanning the external antenna from the detection devices of a system.

The subject invention will be explained in more detail with reference to Figures 1 to 3, which show by way of example, schematically and not limiting advantageous embodiments of the invention. FIG. 1 shows a schematic representation of a system provided with the described system; FIG. Fig. 2 is a schematic representation of a group of objects in a housing provided with a bridging device according to the invention; and Fig. 3 is a schematic illustration of the lock-up device.

The reference numerals of objects that occur repeatedly in the figures are supplemented to distinguish with lowercase letters.

Fig. 1 shows a schematic representation of a plant 4, which is divided into five areas 5a -5e. These areas represent different spatially delimited parts of the plant, for example, machining centers, transport devices, storage areas, test stands, etc. In each area there may be a plurality of different monitoring objects 1a-1h, each monitoring object being provided with an identification element. (For the sake of clarity, in Fig. 1, only the label element 3a of the monitoring object 1a is provided with a reference numeral). Each identification element has a unique identifier that can be read out by corresponding detection devices 6a-6l. The read-out can preferably take place without contact, for example the identification element 3a can be an RFID tag, and the detection device 6a can be an RFID scanner which recognizes the RFID tag in the corresponding area 5a and reads its identifier. The connections 14a-14e between the areas 5a-5e represent transport paths on which the monitored objects 1 can pass from one area to another.

The areas may each have a plurality of detection devices 6a-6l. For example, along the area 5e, five detection devices 6h, 6i, 6j, 6k, and 6I are arranged in parallel with each other, and each scan a specific part of the area 5e. The area 5e could, for example, represent a conveyor or a production or test track, wherein it can be determined by the detection devices 6h to 6I at which position the monitoring objects 1e to 1h present in the area 5e are located. The monitoring objects could, for example, be transport containers in the case of conveyors. On the other hand, the elongated area 5e could be a long workbench or a laboratory bench on which monitoring objects 1e to 1h, for example tools, analyzers, sample containers or other monitoring objects, may be located. By aligning the detection devices 6h to 6I, the respective position of the monitoring objects can be determined very accurately, with a particularly high position accuracy can be achieved by overlapping scan areas, as shown for example in the monitoring object 1h, both in the scan area of the detection device 6k, as also located in the scanning area of the detection device 6I.

The scans of the individual detection devices can be so coordinated with respect to their timing and / or their radio frequencies that they do not interfere with each other.

In the region 5d, two detection devices 6f and 6g are arranged such that their sensor directions intersect, wherein each of the two sensor regions covers substantially the entire surface of the region 5d. The respective sensor areas of the detection devices are indicated by way of example in the figures as dotted wave patterns. The actual extent of the sensor regions may differ significantly from the representation, as will be apparent to those skilled in the art. The intersecting sensor regions allow using not only the presence, but also the position of those located in region 5d by means of known location techniques, such as the time of arrival (TOA) method, by means of phase shifts or angle-dependent methods Monitoring objects (in the illustrated case of the monitoring object 1d) to determine. Other locating techniques may also be used, for example at a distance where the position is e.g. can be measured by signal propagation time or signal strength (examples include ToA, TDoA, E-OTD, RTT or RSSI) in the direction where the position is e.g. angular relationships, such as by triangulation or trilateration, can be measured (as in AOA or DOA decay), on neighborhood relationships (as exemplified by the CoO "Cell of Origin" method), in other methods known to those skilled in the art or based on combinations of these methods.

By the position measurement, not only the position of a single monitoring object can be determined, but it can also be several monitoring objects and their relative positions relative to each other are determined. An evaluation of these relative positions makes it possible to detect even very complex groupings of monitoring objects and to evaluate them accordingly. The position determination can also be extended to a three-dimensional range, for example by providing one or more further detection devices.

The areas 5a and 5c are each provided with only a single detection device 6a or 6e, which determine only the presence of the respective monitoring objects 1a, 1b and 1c in the corresponding area 5a, 5c.

Advantageously, not only areas themselves, but also the transitions between areas can be monitored. In Fig. 1, the connection 14a between the areas 5a and 5b is supervised by its own detection device 6b, which detects when a monitoring object changes from one area to another. The detection device 6b can be arranged, for example, in a door opening between two rooms or at another location, which necessarily has to pass through a surveillance object in order to pass from one area to the next. In principle, a described system could be monitored completely by scanning for objects only at the connections 14a-14e between the individual areas 5a-5e. In this case, it is not absolutely necessary that the detection devices arranged on the connections can also determine the direction of movement of the detected surveillance object, since in a closed system it is known at any time where each surveillance object is currently located, and thus the origin of the surveillance object that is itself just moved through a detection gate is known. However, the provision of redundant detection devices can reduce the susceptibility to errors and increase the reliability of the system.

To allow an overall picture of the monitoring objects in the Appendix 4 at any time, all detection devices 6a to 6I are connected to a computing unit 7, which records all detection events, evaluates and enters into an inventory database 8, from which at any time the system state of Appendix 4, ie determine the monitoring objects present in each of the areas 5a-5e and, where appropriate, their positions. The arithmetic unit can also be used for the time coordination of the scans performed by the individual detection device.

The exact configuration of the areas depends on the particular application and the arrangement of the detection devices can be adapted specifically to the particular conditions of use. The configurations set forth herein are merely exemplary and non-limiting embodiments. Various types of detection devices and marker elements may also be used wherein non-contact and tactile systems may be used in any combination.

The evaluation of the detected monitoring objects in the arithmetic unit 7 makes it possible to combine several monitoring objects, which belong for example to a functional unit, to form an object group. For example, the monitoring objects 1b and 1c, which are detected by the detection device 6e in the region 5c, form an object group 2a.

A further object group 2b, which is arranged in the region 5b in the sensor region of the detection device 6d, is enlarged in FIG. 2 and shown in more detail. The object group 2b shown in FIG. 2 comprises the surveillance objects 1u, 1v, 1w and 1x, which are each provided with an identification element 3u, 3v, 3w or 3x. The identification elements are RFID tags which can be read out contactlessly by the detection device 6d, an RFID sensor. However, the surveillance objects 1u, 1v, 1w and 1x are arranged in a common housing 9, which is provided with its own identification element 3i. The housing 9 with the identification element 3i thus likewise constitutes a monitoring object. The object group 2b therefore consists of the surveillance objects 1 u, 1 v, 1w and 1 x and the housing 9, which form a common unit.

As indicated by the sensor region of the detection device 6d shown schematically, the RFID signals from the housing 9 are shielded. As a result, although the detection device 6d can read the label element 3i attached to the outside of the housing 9, it does not read the label elements 3u, 3v, 3w, and 3x of the monitor objects 1u, 1v, 1w, and 1x enclosed in the housing.

If, for example, the object group 2b is a device to be tested which is arranged in a test environment, it would therefore be possible with a spatially fixed detection device 6d to recognize that the device (ie the object group 2b) is located on the test bench (that is, for example However, no statement could be made about the exact features of the measuring sensor, which are located within the device (ie the housing 9), and their labeling elements are therefore shielded and can not be read.

In order to solve this problem, the housing according to the invention on a lock-up device 13, which allows the detection device 6d, read out the existing inside the housing labeling elements 3u, 3v, 3w and 3x from the outside. In a simple embodiment, this device essentially consists of an outer antenna 11 arranged on the outside of the housing, an inner antenna 10 arranged inside the housing, and a gateway 12 which provides signal transmission between the outer antenna 11 and the inner antenna 10.

In a very simple form, the gateway could be formed as a simple connection line between the outside antenna and the inside antenna, but this simple embodiment would quickly reach technical limits.

In Fig. 3, the transmission device 13 is shown again in more detail. The outer antenna 11 and the inner antenna 10 may each be conventional RFID antennas, which may be integrated, for example, in a label or other non-shielding housing. The gateway 12 may be powered by the power received by the outside antenna, or it may use its own power source for operation, such as a battery 15 or other alternative energy source, such as a solar cell, that uses the ambient lighting to generate power. The gateway can receive and transmit RFID signals both via the external antenna 11 and via the internal antenna 10. In the exemplary embodiment illustrated in FIG. 3, the gateway is disposed on the outside of the housing, but it may also be provided inside the housing in the interior antenna. It could also be both the inner antenna 10, and the outer antenna 11 are each provided with a transponder element, wherein the two transponder elements can communicate with each other, thereby forming the gateway.

The gateway 12 is connected via the connection 16 with the inner antenna. The connection can be designed as a simple cable connection, which is guided over a bore. At the same time, the connection 16 can also be designed as a fastening element with which the inner elements of the transmission device (inner antenna 10 in the case shown) are fastened to the outer elements (in the illustrated case the gateway 12 and the outer antenna 11). Such compounds, such as screw, plug, rivet or adhesive bonds are well known to those skilled in the art. Optionally, the material of the housing 9 can also be used for the communication between the inner antenna 10 and the outer antenna 11, for instance by using the metallic conductivity of a metal housing for the data transmission. In this case, an inner transponder connected to the inner antenna 11 and an outer transponder connected to the outer antenna, which together form the gateway 12, could be applied opposite the metal surface of the housing and communicate with each other across the housing wall via metal contacts. The inner and outer elements of the gateway could be glued to the housing, where they can also be integrated in each case in an adhesive label.

Now, when the outside antenna 11 is activated by an RFID sensor signal 17a output from the detection device 6d, the gateway 12 receives the signal and outputs a corresponding signal 17b via the inside antenna 10 into the inside of the housing. The inner signal 17b can thereby be received by an RFID tag (e.g., the tagging element 3u) inside the housing, thereby activating the tagging element 3u and outputting a response signal 17c, which in turn can be received by the indoor antenna 10. The response signal 17c of the RFID tag is processed by the gateway 12 in the reverse direction and delivered as a corresponding response signal 17d via the outside antenna 11 so that it can be received by the detection device 6d.

In order to avoid interference, the signals 17b and 17c in the interior can use a different frequency than the signals 17a and 17b processed by the detection device 6d. In conjunction with multi-band RFID systems, this makes it possible to create very complex and functionally stable systems.

The gateway serves as a "hub" between the interior of a device, typically within a metallic housing, and the outside space, typically the test cell in which the device is located. This enables communication between a reading station (test bench fixed, ie mounted in the outer space) and an RFID tag attached to a component (located in the interior of the device). Since the metallic housing of the device acts as a faraday cage and shields RF fields, this communication would normally not be possible without a bridging device.

For RFID tags that are applied directly to metal surfaces, or that are to be read in a metal-rich environment, special RFID tags can be used, which are designed for this purpose. Such RFID tags are known in the art and they usually use special antenna arrangements, which are less affected by the disturbing influences of the metallic environment.

The steps of a method which can be carried out with the aid of the described devices will now be described by way of example. The procedure is used to map the stock of monitoring objects that are located in a system in a database and to keep this figure preferably in real time on the current level.

With reference to the example illustrated in FIGS. 1 to 3, by means of the detection devices (6a-6l) associated with the regions (5a-5e), if appropriate using corresponding gateways 12, the unique identifiers of the identification elements present in the regions (3a-3x) read. Alternatively and / or in addition to this, starting from a previously initialized initial status, all movements of identification elements between the areas (5a-5e) and over appropriately defined system boundaries can be recorded in order to track the operating state of the installation. In areas that support position determination, movements within the area can also be detected.

The read-out of the detection devices identifiers are evaluated by the arithmetic unit 7, with which the detection devices are connected, in each case the particular monitoring object, which is assigned to the read from the identification element identifier, is determined. The data concerning the particular monitoring object is then retrieved from the database 8, and the database is updated on the basis of the detection event, if an update is required. An update is required, in particular, if the location of the monitoring object has changed, if the status of the monitoring object has changed, or if the monitoring object has been inserted or removed from a collection. In order to determine whether the state of a monitoring object has changed, other data can also be taken into account, such as data derived from the work procedures performed. For example, the wear of a surveillance object can be determined based on the duration of use. In this way, for example, maintenance and calibration intervals can be determined and warnings automatically issued as soon as a maintenance, calibration or replacement of a monitoring object has to be performed.

Certain monitoring objects can be defined in the database as object groups. If a monitoring object is now being scanned that is assigned to a collection, the procedure can check whether all the other monitoring objects assigned to this collection are also present. If this is not the case, for example, the system may issue a warning or trigger any other workflow previously defined for this case.

In other cases, the system may consist of the detection of a single monitoring

Object to draw conclusions about the entire object group. For example, if a location change is detected by individual monitoring objects of an object group, the method can also change the location of all other monitoring objects of the same group. This may be useful if the object group is permanently assembled and can only be moved together, and / or if there is a probability that some monitoring objects in a group can not be detected due to shielding processes. Such a conclusion is permissible in particular if none of the monitoring objects of the group is detected simultaneously in another area.

On the other hand, in the detection of location changes of a single monitoring object of an object group, it could be concluded that an element of the object group has been removed from the group, and therefore the group is no longer complete. This is the case in particular when other monitoring objects of the same group are detected simultaneously in another area.

In all cases, the detection of a particular event may result in a warning being issued, or any previously defined other workflow may be triggered.

The readout of the identification elements may be timed, for example, at certain intervals, and / or it may be triggered when a certain event occurs, such as when a status of the system is queried during deployment planning, or if an identification element by a certain area (eg an RFID gate) is moved.

The method may further provide steps to verify the integrity of monitoring objects and / or object groups. An integrity check can be done automatically, for example by scanning all tagging elements of the group in the same area, and also checking the spatial arrangement of the monitoring objects, provided that the system has appropriate tracking techniques. Optionally, operator intervention may be required to verify integrity. For example, the system may issue a warning message requesting the user to perform the necessary steps and then confirm. Based on the confirmation, the database can then be supplemented / changed. The integrity check may also include monitoring the maintenance and / or replacement intervals of individual ones of the monitoring objects of a collection.

By keeping in this way the inventory and the status of the monitoring objects in an attachment in the database at any time, it can be checked at any time whether an activity planned on the installation can be carried out with the monitoring objects or object groups present in the installation. This facilitates mission planning and also allows forward-looking planning of future deployments in distributed organizational structures. A team that takes over a plant, for example to carry out a specific test procedure, can immediately check whether a previously defined operating state of the plant has been established. This greatly facilitates the transfer from one team to the next. If necessary, warnings can be issued automatically if the operating state differs from the planning state.

Advantageously, the system described can also be used to monitor the maintenance status of the installation or individual parts thereof by third-party providers, it being possible to precisely regulate which data is to be transmitted to this service provider or can be retrieved from this service, and which not. For example, the data used to locate the monitored objects may remain locally with the owner or user of the plant, and only consistency data may be forwarded to the service provider. This considerably facilitates the planning of maintenance operations for the service provider since he can have the relevant data at any time, and the owner or user of the installation still has security that sensitive data, such as the setup of test and test systems, does not fit into the Third hand arrive.

The consistency data can also be used to detect any product counterfeits used in a system. Original products can e.g. be recognized on the basis of the label element associated serial number. The mere fact that an object is provided with an identification element allows a conclusion as to whether it is an original object. In order to recognize counterfeit identification elements, an encrypted code may also be stored on the identification element, the encryption of which can only be decrypted by the service provider or the producer of the original component.

Claims (6)

claims 1. Bridging device (13) for a housing (9) of an object group (2), which has a plurality of monitoring objects (1) which are each provided with non-contact readable identification elements (3) having a unique identifier, wherein the housing (9) has a shielding effect, characterized in that the bridging device (13) comprises an inner antenna (10), an outer antenna (11), and a gateway (12), which detects a detection elements (3) arranged in the housing (9) via the outer antenna (11). 2. Bridging device according to claim 1, characterized in that the inner antenna (10) and the outer antenna (11) are designed as RFID antennas. 3. Bridging device according to claim 1 or 2, characterized in that the gateway (12) is designed such that it can receive and transmit both via the outer antenna (11) and via the inner antenna (10) RFID signals. 4. Bridging device according to one of the preceding claims, characterized in that both the inner antenna (10) and the outer antenna (11) are each provided with a transponder element, wherein the two transponder elements can communicate with each other and thereby form the gateway (12). 5. Bridging device according to one of the preceding claims, characterized in that the housing (9) is designed such that the metallic conductivity of the housing (9) is used for data transmission. 6. Bridging device according to claim 4 and 5, characterized in that the transponder elements are so applied to the metal surface of the housing (9) opposite, that they can communicate with each other across metal contacts with each other across the housing wall.