Beckhoff product news

Next multi-touch Panel PCs for installation in the front of a control cabinet in display sizes from 7 to 23.8 inches

Next multi-touch Panel PCs for installation in the front of a control cabinet in display sizes from 7 to 23.8 inches

Next multi-touch Panel PCs for mounting arm installation in display sizes from 15.6 to 23.8 inches

Next multi-touch Panel PCs for mounting arm installation in display sizes from 15.6 to 23.8 inches

Same form factor, more computing power: with Intel Atom^® x7, the Industrial PCs are suitable for automation projects in a wide range of applications, whether their requirements be complex or simple.

Same form factor, more computing power: with Intel Atom^® x7, the Industrial PCs are suitable for automation projects in a wide range of applications, whether their requirements be complex or simple.

Same form factor, more computing power: with Intel Atom^® x7, the Industrial PCs are suitable for automation projects in a wide range of applications, whether their requirements be complex or simple.

Control panels for installation in the front of a control cabinet in display sizes from 7 to 23.8 inches

Control panels for mounting arm installation in display sizes from 15.6 to 23.8 inches

The Beckhoff RT Linux^® distribution is a Linux^® platform specially developed for industrial use.

The electrically isolated CX2100-0022 power supply unit extends the existing power supply module portfolio for Embedded PCs by a fanless UPS-OCT-capable version offering a maximum power output of 100 W. It is intended for supplying power to the components of a CX20xx system (CPU modules, system and extension modules) and is suitable for all existing basic CPU modules from the CX20xx series, as long as the maximum power output is not exceeded. The CX2100-0022 power supply unit is passively cooled and thus fanless and maintenance-free. An FSTN LC display with 2 x 16 characters and a selector switch as well as an enter key allow the querying of internal status values as well as self-created display parameters or menus with and without input options. The integrated display is controlled via TwinCAT.

ED serie sets new standard for the future: efficient signal acquisition with modern design, tool-free assembly and app-based diagnostics.

The EL1264 digital input terminal acquires the fast binary 24 V control signals from the process level and transmits them, in an electrically isolated form, to the controller. The EtherCAT Terminal has four channels that indicate their signal state via light emitting diodes. The signals are sampled with an adjustable integer multiple (oversampling factor: n) of the bus cycle frequency (n microcycles per bus cycle). For each bus cycle, the EtherCAT Terminal generates a set of process data that is transferred collectively during the next bus cycle. The time base of the terminal can be synchronized precisely with other EtherCAT devices via distributed clocks. This XFC procedure enables the temporal resolution of the digital input signals to be increased to n times the bus cycle time.

The EL3008-0005 is designed for measuring stacked voltages up to 1500 V CAT II, such as those found in accumulators and fuel cells. The negative pole of one cell is also the positive pole of the next. In combination with the high galvanic isolation to the E-bus, these terminals can be used to record large cell stacks with minimal wiring. This allows cell behavior to be monitored during normal operation and facilitates rapid responses in case of malfunctions.

The EL5001-0012 EtherCAT Terminal allows simulation of single-turn and multi-turn SSI encoders with gray or binary code output and a maximum transmission rate of 2 MHz. This makes it possible to generate a position response to an externally generated SSI master signal in applications where no SSI encoder is physically present. Extensive parameterization options allow optimum simulation of different encoder types.

The EL6233 allows the direct connection of Ethernet-AL-capable field devices. The sensors are supplied in accordance with the SPCX port profile and integrated via PROFINET. Thanks to the flexible EtherCAT system architecture and the EL portfolio, Ethernet-APL, HART or simple digital signals can be integrated in the same terminal segment.

The EL6251 Ethernet Modbus TCP terminal enables distributed connection of any Modbus TCP devices to the EtherCAT terminal network. The EL6251 can work as a Modbus client and Modbus TCP server simultaneously and provides up to eight connections which can be used as desired. The IP address of the connected Modbus server can also be changed by the PLC during operation. The EL6251 has an Ethernet port, meaning that switches must be used when several Modbus TCP devices are connected.

The EL6254 Ethernet Modbus TCP terminal enables distributed connection of any Modbus TCP devices to the EtherCAT terminal network. The EL6254 can work as a Modbus client and Modbus TCP server simultaneously and provides up to eight connections which can be used as desired. The IP address of the connected Modbus server can also be changed by the PLC during operation. The EL6254 has an internal switch with four external ports, meaning that four Modbus TCP devices can be connected without an additional switch.

The EL6685 serves as a high-precision reference clock for the distributed clocks system. For applications with the highest demands on time measurement, the built-in oscillator significantly increases the basic accuracy of the timer.

The EL6685-0010 serves as a high-precision reference clock for the distributed clocks system. For applications with the highest demands on time measurement, the built-in oscillator significantly increases the basic accuracy of the timer.

The ELX3632 EtherCAT Terminal enables direct connection of intrinsically safe IEPE sensors from zone 0/20 and 1/21 hazardous areas. The measuring signals are analyzed via the TwinCAT library on the PC. This enables all benefits of the PC platform, such as performance and flexibility, to be fully exploited. Alternatively, the evaluation can also be performed with the user software. Adjustable filters allow you to customize the terminal to meet your needs.

The EP6224-0044 IO-Link master module enables connection of up to eight IO-Link devices. These can be IO-Link box modules, actuators, sensors or combinations of both. In addition, the EP6224-0044 offers eight further digital inputs or outputs on the eight Class A master ports.

The EP6224-3034 IO-Link master module enables connection of up to eight IO-Link devices. These can be IO-Link box modules, actuators, sensors or combinations of both. In addition, the EP6224-3034 provides a power supply for Class B devices on the eight Class B master ports.

The EPP3754-0002 EtherCAT P Box has four analog multi-functional inputs, which can be parameterized individually and extensively:

The EPP6224-0002 IO-Link master module enables connection of up to four IO-Link devices, e.g. actuators, sensors or combinations of both. In addition, the the EPP6224-0002 offers an additional digital input on each of the four Class A master ports.

The EPX2004-0022 EtherCAT Box enables direct connection of intrinsically safe actuators from zone 0/20 and 1/21 hazardous areas. The EPX2004-0022 supplies an output voltage of 24 V DC and a maximum output current of 50 mA per channel, the sum current is 200 mA. The signal state of the individual channels is indicated by an LED.

The EPX3204-0022 EtherCAT Box enables direct connection of RTDs from zone 0/20 and 1/21 hazardous areas. The EPX3204-0022 circuit can operate sensors in 2-wire, 3-wire and 4-wire technology. Linearization takes place across the entire, freely selectable temperature range. By default, the terminal is set to Pt100 sensors in 4-wire technology. The EPX3204-0022 indicates signal state and sensor faults (e.g. wire break) by means of LEDs.

The EPX3314-0022 EtherCAT Box allows direct connection of thermocouples from zone 0/20 and 1/21 hazardous areas. The EPX3314-0022 circuit can operate sensors in 2-wire technology. Linearization takes place across the entire, freely selectable temperature range. A wire break is signaled by error-LEDs. Cold junction compensation is performed by internal temperature measurement. With the EPX3314-0022, voltage measurement in the mV range is also possible.

The ER9320-0022 EtherCAT Box connects PROFINET RT networks to the EtherCAT Box modules (EPxxxx, ERxxxx and EQxxxx) and converts the telegrams from PROFINET RT to EtherCAT. One station consists of an ER9320-0022 and any number of EtherCAT Box modules. The box is connected to PROFINET RT via a D-coded M12 socket (in/out). With EtherCAT, the PROFINET RT box can use the powerful and ultra-fast I/O system with its large selection of EtherCAT Box modules. The ER9320-0022 supports the PROFINET RT profile and seamlessly fits into PROFINET RT networks.

The BK5160 standard coupler is a CANopen slave that supports the KL, KS, and KM series Bus Terminals. It automatically detects baud rates of up to 1 Mbit/s. The node address can be specified easily and manually using two rotary selector switches. The BK5160 also has a USB-C interface so that the KS2000 software can be used to configure the bus terminals or to enable firmware updates.

The EJ1321 1-port EtherCAT P junction offers the option of converting from an EtherCAT segment to EtherCAT P or extending an EtherCAT P network in line topology.

The EJ5152 EtherCAT plug-in module is an interface for connecting two 24 V DC incremental encoders (24 V HTL) with A and B tracks via the signal distribution board. Alternatively, the EJ5152 can be used as an up or down counter. The encoder can be supplied with 24 V directly via the supply on the signal distribution board.

The EtherCAT SubDevice Controller ASIC ET1150 offers additional functions to those already included in the ET1100.

The EtherCAT IP core enables the EtherCAT communication function and application-specific functions to be implemented on an FPGA (field programmable gate array, an integrated circuit containing programmable logical components). The EtherCAT functionality is freely configurable. The IP core can be combined with your own FPGA designs or integrated into system-on-chips (SoCs) with soft-core processors or hard processor systems via Avalon^® or AMBA^® AXI™ interfaces. The physical interfaces and internal functions, such as the number of FMMUs and SYNC managers and the size of the DPRAM, are configurable. The process data interface (PDI) and the distributed clocks are also configurable. The functions are compatible with the EtherCAT specification and the EtherCAT ASIC ET1100.

The EtherCAT IP core enables the EtherCAT communication function and application-specific functions to be implemented on an FPGA (field programmable gate array, an integrated circuit containing programmable logical components). The EtherCAT functionality is freely configurable. The IP core can be combined with your own FPGA designs or integrated into system-on-chips (SoCs) with soft-core processors or hard processor systems via AMBA^® AXI™ interfaces. The physical interfaces and internal functions, such as the number of FMMUs and SYNC managers and the size of the DPRAM, are configurable. The process data interface (PDI) and the distributed clocks are also configurable. The functions are compatible with the EtherCAT specification and the EtherCAT ASIC ET1100.

The EtherCAT IP core enables the EtherCAT communication function and application-specific functions to be implemented on an FPGA (field programmable gate array, an integrated circuit containing programmable logical components). The EtherCAT functionality is freely configurable. The IP core can be combined with your own FPGA designs or integrated into system-on-chips (SoCs) with soft-core processors or hard processor systems via AMBA^® AXI™ interfaces. The physical interfaces and internal functions, such as the number of FMMUs and SYNC managers and the size of the DPRAM, are configurable. The process data interface (PDI) and the distributed clocks are also configurable. The functions are compatible with the EtherCAT specification and the EtherCAT ASIC ET1100.

The EtherCAT IP core enables the EtherCAT communication function and application-specific functions to be implemented on an FPGA (field programmable gate array, an integrated circuit containing programmable logical components). The EtherCAT functionality is freely configurable. The IP core can be combined with your own FPGA designs or integrated into system-on-chips (SoCs) with soft-core processors or hard processor systems via AMBA^® AXI™ interfaces. The physical interfaces and internal functions, such as the number of FMMUs and SYNC managers and the size of the DPRAM, are configurable. The process data interface (PDI) and the distributed clocks are also configurable. The functions are compatible with the EtherCAT specification and the EtherCAT ASIC ET1100.

The SCT4xxx differential current transformers were designed for detecting differential currents (earth fault currents) type A. A differential current measurement can already detect very low error currents as well as various leakage currents. Continuous monitoring is necessary to be able to separate these from each other. This allows early detection of changes that may be indicative of degenerating insulation. The SCT4xxx differential current transformers thus enable condition-based maintenance and save operators the increased costs of previous blind maintenance intervals.

The SCT4xxx differential current transformers were designed for detecting differential currents (earth fault currents) type A. A differential current measurement can already detect very low error currents as well as various leakage currents. Continuous monitoring is necessary to be able to separate these from each other. This allows early detection of changes that may be indicative of degenerating insulation. The SCT4xxx differential current transformers thus enable condition-based maintenance and save operators the increased costs of previous blind maintenance intervals.

The SCT4xxx differential current transformers were designed for detecting differential currents (earth fault currents) type A. A differential current measurement can already detect very low error currents as well as various leakage currents. Continuous monitoring is necessary to be able to separate these from each other. This allows early detection of changes that may be indicative of degenerating insulation. The SCT4xxx differential current transformers thus enable condition-based maintenance and save operators the increased costs of previous blind maintenance intervals.

The SCT4xxx differential current transformers were designed for detecting differential currents (earth fault currents) type A. A differential current measurement can already detect very low error currents as well as various leakage currents. Continuous monitoring is necessary to be able to separate these from each other. This allows early detection of changes that may be indicative of degenerating insulation. The SCT4xxx differential current transformers thus enable condition-based maintenance and save operators the increased costs of previous blind maintenance intervals.

The SCT4xxx differential current transformers were designed for detecting differential currents (earth fault currents) type A. A differential current measurement can already detect very low error currents as well as various leakage currents. Continuous monitoring is necessary to be able to separate these from each other. This allows early detection of changes that may be indicative of degenerating insulation. The SCT4xxx differential current transformers thus enable condition-based maintenance and save operators the increased costs of previous blind maintenance intervals.

The SCT4xxx differential current transformers were designed for detecting differential currents (earth fault currents) type A. A differential current measurement can already detect very low error currents as well as various leakage currents. Continuous monitoring is necessary to be able to separate these from each other. This allows early detection of changes that may be indicative of degenerating insulation. The SCT4xxx differential current transformers thus enable condition-based maintenance and save operators the increased costs of previous blind maintenance intervals.

The SCT4xxx differential current transformers were designed for detecting differential currents (earth fault currents) type A. A differential current measurement can already detect very low error currents as well as various leakage currents. Continuous monitoring is necessary to be able to separate these from each other. This allows early detection of changes that may be indicative of degenerating insulation. The SCT4xxx differential current transformers thus enable condition-based maintenance and save operators the increased costs of previous blind maintenance intervals.

The separable 3-phase measuring system SCL6xxx with RJ45 connection enables flexible retrofitting without splitting the primary conductors.

The SVL1xxx measuring system with RJ45 connection enables 3-phase voltage measurement of the primary conductors.

High-performance drive solution with an optimized price/performance ratio and no compromise on performance or quality.

The AM1000 servomotors meet the highest technological demands with an optimized price/performance ratio for cost-sensitive applications.

The AX1000 economy servo drive for implementing demanding and cost-sensitive drive tasks.

The variable frequency drives in the AF1000 series are particularly suitable for performing basic drive tasks cost-effectively.

The AF1000 economy variable frequency drives are a cost-efficient series for basic drive tasks. The AF1155-3xxx single-axis module is available in the higher power range with a rated output power of 5,5 kW with a three-phase supply of 3 x 208…480 V AC.

The AX1000 economy servo drives are a particularly cost-efficient series that meets the highest technological standards. The AX1112-3xxx single-axis module is available in the higher power range with a rated output current of 12 A with a three-phase supply of 3 x 208…480 V AC. Despite its compact dimensions, it still incorporates an integrated power supply for 24 V DC, DC link capacitors, a braking circuit, and – in most variants – a braking resistor. The power supply generates the control voltage from the DC link voltage.

The ASI8121 combines stepper motor, output stage and fieldbus connection in the voltage range of up to 48 V DC with a standstill torque of 0.75 Nm in the power range up to 250 W.

The ASI8122 combines stepper motor, output stage and fieldbus connection in the voltage range of up to 48 V DC with a standstill torque of 1.40 Nm in the power range up to 250 W.

The ASI8123 combines stepper motor, output stage and fieldbus connection in the voltage range of up to 48 V DC with a standstill torque of 2.35 Nm in the power range up to 250 W.

The ASI8124 combines stepper motor, output stage and fieldbus connection in the voltage range of up to 48 V DC with a standstill torque of 2.50 Nm in the power range up to 250 W.

The motor modules with the product designation ATH202x are elements for the construction of curved XTS track sections for demanding environmental conditions. They represent a 22.5° curve segment (outside curve) of a circle with a diameter of 1273 mm. Via plug-in contacts for the transmission of power and communication, a connection between the motor modules can be established very simply with the help of a cover. The cover contains the necessary contacts for the connection of two motor modules and is optionally also available with a supply cable in order to serve as a power supply point. The subsequent relocation of the power supply points or a change in the number of power supplies is possible without dismounting the motor modules.

Beckhoff offers a machine learning (ML) solution that is seamlessly integrated into TwinCAT 3.

TwinCAT CoAgent offers comprehensive, intelligent support and combines state-of-the-art generative AI models with custom-developed AI agents.

Beckhoff presents the latest generation of motion software solutions in TwinCAT MC3.

New chart type in TwinCAT Scope for 3D visualizations

Completely new chart type in the established TwinCAT Scope product

Automatic PLC code generation for protocols compliant with IEC 60870-5-10x

Overview of the latest TwinCAT 3 software updates

TwinCAT 3 Interface for SOLIDWORKS^® is a tool for easy configuration of a coupling between TwinCAT and the SOLIDWORKS^® 3D CAD software from Dassault Systemès. The aim of this coupling is to create a software-in-the-loop simulation (SiL) of the target sequence of a machine or system to support virtual commissioning.

TwinCAT 3 Interface for NX™ Mechatronics Concept Designer™ is a tool for easy configuration of a coupling between TwinCAT and the NX™ Mechatronics Concept Designer™ 3D CAD software from Siemens. The aim of this coupling is to create a software-in-the-loop simulation (SiL) of the target sequence of a machine or system to support virtual commissioning.

TwinCAT 3 CoAgent for Engineering is the intelligent AI assistant that provides efficient support for PLC development, I/O configuration, and human-machine interface creation. Requirements can be formulated in normal language and TwinCAT CoAgent for Engineering suggests suitable code and configurations, taking existing project structures into account. Flexible mode selection enables custom support based on the task at hand. In addition, TwinCAT CoAgent for Engineering offers direct access to the documentation in the Beckhoff Information System and provides context-related recommendations for accelerated high-quality project implementation.

TwinCAT 3 Analytics Vision offers the option of configuring and testing vision algorithms in a simple graphical representation for an application. No programming skills are required. PLC code based on TF7xxx vision products and an HTML-based dashboard can be generated automatically from the created configuration at the touch of a button. The generated code can be integrated into the machine control system and executed locally. Alternatively, the code can be loaded onto a remote device and image processing can be carried out there.

TwinCAT 3 Analytics Energy offers the option of configuring and testing algorithms for evaluating electrical energy systems in a simple graphical display for an application. No programming skills are required. PLC code based on the TF3650 and TF83xx products and an HTML-based dashboard can be generated automatically from the created configuration at the touch of a button. The generated code can be used to continuously monitor RMS values for current and voltage, frequencies, harmonics, and other characteristic values to assess the grid quality. A particular advantage is that the analysis can also be linked directly to an I/O configuration so that the user can only use a TwinCAT project if required.

TwinCAT 3 Analytics Condition Monitoring offers the option of configuring and testing algorithms for evaluating mechanical and electrical components in a simple graphical display for an application. No programming skills are required. PLC code based on the TF3600 Condition Monitoring library and an HTML-based dashboard can be generated automatically from the created configuration at the touch of a button. The generated code can be used to continuously monitor the components of a machine. A particular advantage is that the analysis can also be linked directly to an I/O configuration so that the user can only use a TwinCAT project if required.

TE3851 TwinCAT 3 MLC Computer Vision is an extension package for the basic TE3850 TwinCAT 3 Machine Learning Creator web application. This extension allows AI models to be created for image processing, e.g. image classification, anomaly detection, and object recognition.

TE3852 TwinCAT 3 MLC Signals and Time Series is an extension package for the basic TE3850 TwinCAT 3 Machine Learning Creator web application. This extension enables creation of AI models for signals and time series, e.g. classification, anomaly detection, and forecasting.

TE3860 TwinCAT 3 MLC Resource Pack is an extension package for the basic TE3850 TwinCAT 3 Machine Learning Creator web application. If more computing time is required, for example for training further AI models, additional computing time can be flexibly obtained via this extension package.

The TwinCAT 3 Restricted Runtime license was specially developed for use in continuous integration, continuous deployment, and simulation processes. It enables flexible, recurrent use in development and test environments but is not intended for live operation. The scope of delivery includes a defined selection of runtime licenses for TwinCAT 3 products that are specifically tailored to simulation and automation tests. The basic license must be purchased in order to use the Restricted Runtime license. This basic license is required so that further machines can subsequently be equipped with sub-licenses and used in development and test environments.

TwinCAT 3 CoAgent for Operations is the intelligent AI assistant that provides efficient support in machine operation, maintenance, and system diagnostics. Operating and maintenance tasks are described in natural language. The CoAgent then provides specific recommendations for action, diagnostics, or direct system commands based on the current machine and process data.

The TwinCAT 3 HMI Database Extension enables data exchange between TwinCAT HMI and database systems. Communication can take place via the standardized ODBC interface or via native database protocols. The analyses of the database can be configured for HMI user interactions or triggered by events in the PLC. The results can be displayed and edited with the TwinCAT HMI controls.

TwinCAT 3 CNC Conveyor Tracking enables a machine to be synchronized with workpieces on a conveyor system. These moving workpieces or parts can be manipulated or processed.

Beckhoff has an attractive software package for creating advanced and intuitive human-machine interfaces for CNC-controlled machines: the TF5310 TwinCAT 3 CNC HMI Base library. It is based entirely on the TF2000 TwinCAT 3 HMI Server and therefore integrates seamlessly into the TwinCAT HMI product family.

The TF5320 Simulation Server connects the 3D simulation control element (which is included in the TwinCAT 3 CNC HMI Base package (TF5310)) to the real-time data from TwinCAT CNC. The server accesses the current tool's data and the blank definition stored in the NC program. The simulation runs either in sync with the actual machining (real-time simulation) or in fast forward without actual axis movement using the contour visualization modes available in TwinCAT CNC. This allows the NC program to be visually checked in advance.

TwinCAT MC3 represents the next generation of motion control, combining the proven capabilities of TF5000 TwinCAT 3 NC PTP with major enhancements designed to boost performance and flexibility. Powered by TF5500 TwinCAT 3 MC3 Base, this new motion control system integrates seamlessly into TwinCAT to deliver an efficient, end-to-end automation solution.

TwinCAT 3 MC3 Axes Packs expand TF5500 TwinCAT 3 MC3 Base with additional axis licenses.

In addition to the control of Beckhoff axes, TwinCAT 3 MC3 also supports the control of axes from other manufacturers;

TwinCAT 3 MC3 Camming extends TF5500 TwinCAT 3 MC3 Base with non-linear couplings (cam plates) between axes.

TwinCAT 3 MC3 Fluid Power expands TF5500 TwinCAT 3 MC3 Base with complete hydraulic integration in TwinCAT. It offers manufacturer-independent control of position, speed, and pressure/force.

TwinCAT 3 Power Collector provides software modules for programming applications for power measurement. These modules offer a standardized interface for all terminals in the EL34xx series. Parameters such as transformer ratio and frequency range can be configured automatically. Interfaces for advanced transmission protocols such as MQTT, HTTP REST, and OPC UA have already been implemented. Telecontrol protocols such as IEC 61850 and IEC 60870 are also available.

TwinCAT 3 Power Technologies provides software modules for programming in-depth diagnostics in electrical power measurement based on the EL37x3. In addition, the same standardized interface as the one in TF8330 TwinCAT 3 Power Collector is available. Real-time optimized calculations of the effective values, frequency, harmonics, distortions etc. are delivered continuously in a 1 ms cycle. Advanced frequency determination methods and an instant Clarke/Park transform are included.

TwinCAT 3 Power Control provides software blocks for implementing a power plant controller. This is required for all power-generating systems in order to meet the grid requirements, in accordance with the standards of the individual European countries, e.g. VDE-AR-N 4110 and VDE-AR-N 4120 and VDE-AR-N 4130 in Germany. This certificate has only been issued for CX8200, CX8290, CX9240, CX5330, and CX5340 Embedded PCs.