WO2022069034A1 - Adaptation module for network elements - Google Patents

Abstract

The invention relates to an adaptation module (100) for connecting network elements (210, 212, 214) to a data network, e.g. an advanced physical layer (APL) Ethernet network in process automation, regardless of type. The adaptation module (100) is designed so as, according to the direction of communication, to convert data from the data network (208) into analogue or digital signals for an analogue or digital network element type, e.g. sensor or actuator, or to convert analogue signals into data for the data network (208), in order to connect a network element (210, 212, 214) of analogue type to the data network (208).

Description

Adaptation module for network elements

field of invention

The invention relates to an adaptation module for connecting network elements to a data network, for example an Advanced Physical Layer (APL) Ethernet network in process automation, regardless of type, a data transmission system that has such an adaptation module, and the use of such an adaptation module.

Background of the Invention

Devices in process automation such as sensors, control units, actuators, display devices, etc. usually communicate via fieldbuses. Fieldbuses can transmit data digitally according to a protocol or transmit analog signals via special lines. An Ethernet connection can be used for digital signals. However, existing analogue sensors cannot be integrated directly into a digital network. The same applies to many of the existing digital sensors.

Summary of the Invention

It is therefore the object of the invention to create a possibility for integrating network elements of the most varied types into a data network.

The object is solved by the subject matter of the independent patent claims. Advantageous embodiments are the subject matter of the dependent claims, the following description and the figures.

The described embodiments similarly relate to the adaptation module for the type-independent connection of network elements with an Advanced Physical Layer (APL) Ethernet network in process automation, the data transmission system, and the use of such an adaptation module. Synergy effects may result from various combinations of embodiments, although they may not be described in detail.

Other variations of the disclosed embodiments may be understood and practiced by those skilled in the art upon practicing the claimed invention through a study of the drawings, the disclosure, and the appended claims. In the claims, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality. A single processor or other entity may perform the functions of multiple items or steps recited in the claims. The mere fact that particular measures are recited in dependent claims does not mean that a combination of those measures cannot be used to advantage.

According to a first aspect, an adaptation module for the type-independent connection of network elements of a data network or for the connection of network elements with a data network, for example an Advanced Physical Layer (APL) Ethernet network in process automation, is provided. The adaptation module is set up, according to the direction of communication, to convert data, e.g. APL Ethernet data, from the data network into analog signals for an analog network element type or to convert analog signals into data for the data network in order to connect a network element of analog type to the data network .

An analog sensor or other network element that is connected to the adaptation module can thereby communicate with other components in a data transmission system via the data network, in particular a process automation network. Depending on the type of device and application, communication can be unidirectional in one direction or the other, or bidirectional. The adaptation module has interfaces, for example, which are compatible with the sensor or device on the one hand and compatible with the protocol used, in particular the physical layer, for example according to the APL standard, on the other hand. Thus, an analog sensor or an analog device can be linked or integrated into the data transmission system in a simple manner. The term "signal" is used in this disclosure in connection with the transmission of analog voltages or analog currents. To differentiate this, the term "data" is used in connection with the transmission of digital voltages or currents. A “digital signal”, such as a digital control signal, is therefore also covered by the term “data” in this disclosure. Furthermore, the data can be data or signals in the physical layer, so that it is not only user data, but also transport data including packed user data in a specified physical form, for example generated according to the layer model.

The term "type" in "type-independent" refers to whether a network element, in particular a network element, is an analog or a digital device type. This means that in the case of a type-independent connection of network elements, an analog device can be communicatively connected to a digital device, or the devices can be connected to one another with devices of the same type in the sense of analog/digital.

Process automation or process automation in the industrial environment can be understood as a sub-area of technology that includes all measures for the operation of machines and systems without human intervention. One goal of process automation is to automate the interaction of individual components of a plant in the chemical, food, pharmaceutical, petroleum, paper, cement, shipping or mining sectors. A large number of sensors can be used for this purpose, which are particularly adapted to the specific requirements of the process industry, such as mechanical stability, insensitivity to contamination, extreme temperatures and extreme pressures.

Measured values from these sensors are usually transmitted to a control room, in which process parameters such as fill level, limit level, flow rate, pressure or density can be monitored and settings for the entire plant can be changed manually or automatically.

A sub-area of process automation or process automation in the industrial environment relates to logistics automation. With the help of distance and angle sensors, processes within a building or within a single logistics facility are automated in the field of logistics automation. Typical applications are, for example, systems for logistics automation in the area of baggage and freight handling at airports, in the area of traffic monitoring (toll systems), in retail, in parcel distribution or else in the field of building security (access control). What the above examples have in common is that presence detection in combination with precise measurement of the size and position of an object is required by the respective application.

Sensors based on optical measuring methods using lasers, LEDs, 2D cameras or 3D cameras, which record distances according to the transit time principle (time of flight, ToF), can be used for this purpose.

Another sub-area of process automation in the industrial environment relates to factory/manufacturing automation. Use cases for this can be found in a wide variety of industries such as automobile manufacturing, food production, the pharmaceutical industry or generally in the field of packaging. The aim of factory automation is to automate the production of goods using machines, production lines and/or robots, i. H. run without human intervention. The sensors used here and the specific requirements with regard to the measurement accuracy when detecting the position and size of an object are comparable to those in the previous example of logistics automation.

A network element is to be understood in particular as a process automation device. A "process automation device" is a process automation device in a process automation network. Such a device may be, for example, a sensor, actuator, controller, display device, or other device, as discussed more fully below. Unless otherwise described, the term “device” in this disclosure means in particular such a process automation device. However, a network element can also be a sensor, controller, etc. in a network other than a process automation network. In this disclosure, the term “device” therefore also generally includes a network device such as a sensor, control unit, etc. in any data network or data transmission system that has a data network.

The higher layer network protocols used in the data network can be, for example, EtherNet/IP, HART (Highway Addressable Remote Transducer)-IP, OPC-UA (Open Platform Communications Unified Architecture), PROFINET, or any other protocol. The physical layer can be, for example, Ethernet, Fast-Ethernet, Gigabit, Wifi, APL (Advanced Physical Layer) or a physical layer of any other protocol. The configuration or setup of the adjustment module can be provided at least in part by software, a program or computer program, a program element and/or hard-wired logic. The program element can be a part of a computer program, but it can also be an entire program in itself. For example, the program element can be used to update an already existing computer program in order to arrive at the present invention. The programmed logic may be stored on a computer-readable medium, which may be considered a storage medium, such as a thumb drive, CD, DVD, data storage device, hard drive, or any other storage medium.

To bring the programmed or hardwired logic into effect, the customization module may include a processor, a general purpose central processing unit (CPU), a graphics processing unit (GPU), a microcontroller, a microcomputer, a programmable logic controller (PLC), a reduced instruction set processor ( RISC processor), an FPGA (Field Programmable Gate Array), a digital signal processing device (DSP), an application specific integrated circuit (ASIC) and/or other programmable circuits or processing devices.

According to one embodiment, the adaptation module is further set up to convert data of a network element of digital type into data for the data network according to the communication direction to convert data from the data network into digital data for the network element of digital type.

In other words, a digital network element can also be connected to the adaptation module. The digital data are brought into a form that corresponds to the relevant standard or protocol, for example the APL standard. While with an analogue type the data still has to be converted from analogue to digital, this is not necessary with the digital type. However, the data must be packed for transmission in accordance with the Ethernet standard, for example. In particular, the data must pass through the layers of the protocol used up to the physical level. The term "convert" is therefore to be understood as protocol conversion up to the physical layer. This means that even if the data is already available according to the data link layer (OSI Layer 2), the conversion would make the data link layer data available be made according to the APL standard with regard to the physical layer (OSI Layer 1), for example.

According to one embodiment, the adaptation module is also set up to pass data through from or to a network element of a data network-compatible type in accordance with the communication direction. This means that a protocol-compliant, e.g. APL-compliant, digital device can also be connected to the adaptation module. In this case, no conversion is necessary. The data provided by the device is already physically in a form that corresponds to the standard and can therefore be sent directly from the device to the device receiving the data via the Ethernet lines, for example. The data generated by the device is then "pushed through" by the adaptation module. The passing through does not exclude the processing of the data. For example, a clock or the edges of the digital voltage transitions or voltage levels can be recovered, or filters can be run through, for example.

According to one embodiment, the adaptation module is further set up to provide the power supply according to a specification of the network element type to be connected. For example, the device is an actuator of a specification type that provides sufficient power supply. The customization module is set up to meet the specification of this specification type. The adaptation module can also be designed in such a way that it can be programmed by the user according to a device specification and can provide a corresponding voltage and current supply. According to one embodiment, the adaptation module can also contain a parameterizable threshold value in order to generate an analog or digital signal when this value is exceeded. The hardware interface, i.e. e.g. sockets, plug connections and cables, can be preconfigured here.

According to one embodiment, the adaptation module is integrated into a network element or mechanically connected to a network element. The adaptation module can thus be both an independent device with a housing and also part of an independent device, or else a module with or without a housing that is integrated into a network element. For example, an existing device can accommodate an expansion card that includes the adjustment module. The card could also have a hardware interface. Furthermore, an existing device For example, receive a modified housing so that the adjustment module can be accommodated in the device and the hardware interface can be retrofitted. "Mechanically connected" means that the adjustment module is attached to the device, for example, by a screw connection, a click fastener, a retaining bracket or in some other way. As a result, the adjustment module can be quickly and easily attached and also detached from the device again.

For example, the adjustment module can be located in a control cabinet and connected to the existing wiring of a device in order to be able to transfer this to the data network, e.g. APL network, without great effort.

According to one embodiment, the adaptation module has a wireless communication unit and is set up to communicate wirelessly with a network element of analog or digital type. For example, the device transmits user data via the radio interface using a radio protocol to the adaptation module, which converts the user data into an APL Ethernet format, for example, or vice versa. Such a radio protocol can be a protocol known to those skilled in the art, such as NFC, GSM, UMTS, 5G, WIFI, Zigbee, Bluetooth, LoRa, etc., or a proprietary protocol.

According to one embodiment, the adaptation module is set up to convert data and/or signals from a number of and/or for a number of network elements of the same or different type. This means that the adaptation module can have multiple interfaces. Several identical or different devices can then be connected simultaneously via the interfaces. In particular, mixed analog and digital devices can also be connected to the adaptation module. If the hardware interface for devices with different communication standards is the same, provision can also be made for these devices to be connected to the adaptation module via this interface as required. The electrical/electronic connection and the processing of the protocol can then be switched over manually, i.e. with the participation of an operator and/or e.g. using a predefined configuration, or the adaptation module automatically recognizes the protocol used or the standard of the device.

According to a further embodiment, the adjustment module has a display for displaying status information. Status information is, for example, information about the connection status or about the successful connection of the device, measurement data of the device or an operating state of the adjustment module.

According to a further embodiment, the adjustment module has a user interface. For example, the user interface could be used to disconnect, remotely control the fitting module, select or change a configuration, and even send commands to the device, for example, to request specific information from the device, such as battery level, configuration parameters, etc. if the device is set up for it. Such a user interface can be, for example, an interface to a smartphone or an app on a smartphone, manual on-site operation or it could be an interface to a server for operation and status information to be displayed. This would make it possible, for example, to collect and display information about the current network structure, to operate remote maintenance and update the software of the adjustment module, etc.

According to one embodiment, the network elements are process automation devices and the data network is an Advanced Physical Layer (APL) Ethernet network in process automation. The adaptation module is set up for the type-independent connection of process automation devices. It is further set up to convert APL Ethernet data from the APL Ethernet network into analog or digital signals for an analog or digital type of process automation device or to convert analog or digital signals into APL data for the APL Ethernet network, to connect a process automation device of analogue or digital type to the data network. The embodiments described above can accordingly be related in particular to an adaptation module in an APL Ethernet network.

Ethernet-APL is a logical extension for Ethernet, or a physical layer that can support EtherNet/IP, HART-IP, OPC-UA, PROFINET or any other higher-level protocol. With APL, all types of explosion protection, especially intrinsic safety, can be implemented with simple verification procedures. In particular, an encapsulated sensor, which cannot actually be used in the so-called EX area because of its fieldbus connection, can still be operated in the network with an integrated adaptation module.

Furthermore, old 2-wire HART (Highway Addressable Remote Transducer) devices more data, including previously unused data, can be made available faster and more efficiently by upgrading with an APL adaptation module. The sensors are therefore available for "Big Data / Industry 4.0".

According to a further aspect there is provided a data transmission system comprising such an adaptation module, as well as a network element of analog or digital type and a data network. In this case, the data transmission system is set up to provide communication between the network element of the analog or digital type and another device of the data transmission system by means of the adaptation module via the data network. That is, a network element in the data transmission system is connected to the adaptation module. A communication to another device of the data transmission system is made possible by means of the adaptation module via the data network. In e.g. an APL network, the devices communicating with each other need not have APL functionality and can be of analog type or digital type.

According to one embodiment, the network element is a filling level sensor, a limit level sensor, a pressure sensor, an actuator, a control device, a display device, an evaluation device or another field device or mobile or stationary device.

According to a further aspect, use of the adaptation module described above is provided in a data transmission system set out above, in particular in a process automation network.

Brief description of the figures

Exemplary embodiments of the invention are described in detail below with reference to the enclosed figures. Neither the description nor the figures should be construed as limiting the invention. Here shows

1 is a block diagram of an adjustment module according to an embodiment.

2 shows a block diagram of a data transmission system according to an embodiment. The drawings are merely schematic and not to scale. In principle, identical or similar parts are provided with the same reference symbols.

Detailed description of the figures

1 and 2 show an embodiment of an adaptation module 100 for the type-independent connection of network elements, e.g the communication direction in this example converting APL Ethernet data from the Advanced Physical Layer (APL) Ethernet network 208 into analog signals for an analog process automation device type or converting analog signals into APL Ethernet data for the APL Ethernet network to connect an analog type network element to the APL Ethernet network 208. For this purpose, the adaptation module 100 has a connection 101 for connection to the APL network 208 . Furthermore, the adaptation module 100 has an interface 102 as a connection option to a network element 210, 212, 214, such as analog and/or digital actuators and/or sensors. In the example in FIG. 1, the interface 102 has a connection 105 for analog signals, with which analog signals in the 0-10 V range can be transmitted. Power-intensive sensors/actuators can be integrated into the APL network. For example, an existing analog sensor 214 with an I IC interface for on-site parameterization with a 4...20 mA output and the I IC interface could be integrated into an APL network 208 via the adaptation module 100 . For this purpose, the adaptation module 100 has an analog interface 104 for, for example, currents of 4 to 20 mA or, for example, 22 mA sensor interference currents, as well as a digital input/output interface (digital input/output, DIO) 106. This means that further information from the sensor is im APL network 208 available. Furthermore, devices with a fieldbus interface can be connected to the connection 107 in the adaptation module 100 shown in FIG. 1 . The adaptation module 100 also has a converter 110 for converting analog signals to the APL protocol, a converter 111 for converting digital signals to the APL protocol, and a converter 112 for converting signals from any other field bus to the APL Protocol. The adaptation module 100 can be designed for a specific input signal or for a number of input signals. Furthermore, the connections 104, 105, 106, 107 can be present more than once. This means that a number of sensors/actuators can also be connected to the adaptation module 100 . Optionally, the adjustment module 100 can include a visual display 120 in order to display status information, operating states, etc. of the adjustment module 100, the network 200 or the connected devices 210, 212, 214, for example.

Optionally, the adjustment module 100 can be operated manually on site or via software, such as an app on a smartphone, tablet or other mobile device.

Optionally, the connected device 210, 212, 214 can be supplied with energy directly from the APL network via the adaptation module 100. For this purpose, the adjustment module 100 can have a connection 108 for providing the electrical energy to the device 210, 212, 214.

As outlined in FIG. 2, the adaptation module 100 can be mounted directly on the sensor, as shown for the sensor 214, integrated into the sensor 214, as shown for the sensor 210, or mounted remotely as a stand-alone module, as for the Sensor 212 shown. The connection between the adjustment module 100 and the sensors 210, 212, 214 can be wired 224 or wireless 226, so that wiring can be saved.

Sensor 210 is, for example, a filling level sensor that is designed as a radar sensor and has a Profibus PA. The adaptation module 100 is integrated into the sensor 210 or mounted on the sensor 210, for example. The adjustment module 100 receives the output data of the level sensor 210 via the connection 107 of the adjustment module. The adaptation module 100 packs the data and makes them available at the output 101 in accordance with the APL Ethernet requirements, from where they are routed to a switch of the APL Ethernet network 208 via the connection 222 . The APL Ethernet network 208 is connected via Ethernet to APL power switches or APL power switches 206, which can switch the sensor on or off or supply it with energy.

Similarly, in a second example, device 212 is a 2-wire 4-20 mA HART analog level sensor that can be parameterized via terminal 104 . The fill level sensor 212 sends its data, for example, via the radio link 226 or the wired link 224 to the adjustment module 100, which is an independent module in this example. The adaptation module 100 converts the data with the Converter 110 to the APL protocol and sends the converted data according to the APL Eth em et Proto ko II via the output 101 to an APL field switch that is part of the APL Ethern et network 208; and thus establishes the connection between the sensor 212 and the APL Ethernet network 208.

In a third example, the device 214 is a point level sensor, which is designed as a vibration switch, for example. In this example, the adjustment module 100 is integrated into the cable gland of the vibration switch 214 .

The communication, including the conversion, can also take place in the other direction, i.e. from the APL Ethernet network 208 via the adaptation module 100 to the devices or sensors 210, 212, 214.

In this way, further control devices (e.g. PLC) can be saved and existing system parts can be integrated into the APL network 208 when the system is modified or renewed. Existing sensors and actuators can be easily integrated into the cloud via the APL network 206. In this case, existing analog and/or digital actuators can be integrated directly into the APL network 206 . Furthermore, the data transmission system 200 can be maintained proactively.

Claims

Expectations

1 . Adaptation module (100) for the type-independent connection of network elements (210, 212, 214) of a data network; wherein the adaptation module (100) is set up, according to the communication direction, to convert data from the data network into analog signals for an analog network element type or to convert analog signals into data for the data network in order to connect a network element (210, 212, 214) of the analog type to the to connect data network (208).

2. Adjustment module (100) according to claim 1, wherein the adjustment module (100) is further set up, according to the direction of communication, to convert data of a network element (210, 212, 214) of digital type into data for the data network (208) or to convert data from the data network ( 208) into digital data for the network element (210, 212, 214) of digital type.

3. Adjustment module (100) according to claim 1 or 2, wherein the adjustment module (100) is further set up to pass data from or to a network element (210, 212, 214) of a data network-compatible type according to the communication direction.

4. Adjustment module (100) according to any one of the preceding claims, wherein the adjustment module (100) is further configured to provide the power supply according to a specification of the element type to be connected.

5. Adjustment module (100) according to any one of the preceding claims, wherein the adjustment module (100) is integrated into a network element (210, 212, 214) or is mechanically connected to a network element (210, 212, 214).

6. Adjustment module (100) according to any one of the preceding claims, wherein the adjustment module (100) comprises a wireless communication unit and is arranged to communicate wirelessly with a network element (210, 212, 214) of analog or digital type.

7. adjustment module (100) according to any one of the preceding claims, wherein the adjustment module (100) is set up, data and / or signals from a plurality and / or for to convert several network elements (210, 212, 214) of the same or different type.

8. Adjustment module (100) according to any one of the preceding claims, wherein the adjustment module (100) has a display (120) for displaying status information.

9. Adjustment module (100) according to any one of the preceding claims, wherein the adjustment module (100) has a user interface.

10. Adjustment module (100) according to any one of the preceding claims, wherein the network elements are process automation devices, the data network is an advanced physical layer (APL) Ethernet network in process automation, and the adjustment module (100) is set up for connecting process automation devices independently of the type , and is further set up to convert APL Ethernet data from the APL Ethernet network into analog or digital signals for an analog or digital type of process automation device or to convert analog or digital signals into APL data for the APL Ethernet network, to connect a process automation device (210, 212, 214) of analog or digital type to the data network (208).

11 . Data transmission system (200), comprising an adaptation module (100) according to any one of claims 1 to 10; a network element (210, 212, 214) of analog or digital type; and a data network (208); wherein the data transmission system (200) is set up to provide communication of the network element (210, 212, 214) of analog or digital type with another device of the data transmission system (200) by means of the adaptation module (100) via the data network (208).

12. Data transmission system (200) according to claim 11, wherein the network element (210, 212, 214) is a filling level sensor, a limit level sensor, a pressure sensor, an actuator, a control device, a display device or an evaluation device.

13. Use of an adaptation module (100) according to any one of claims 1-10 in a data transmission system (200) according to any one of claims 11 to 12, in particular in a process automation network.