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Certificates: Certificate "PLC specialist with EPLAN"
Electromobility" certificate -
Additional Certificates: Certificate "PLC: Working with Simatic S7 in the TIA Portal"
Certificate "PLC: Visualization, process data processing with WinCC and networking in the TIA Portal"
Certificate "Electrical planning with EPLAN" -
Examination: Praxisbezogene Projektarbeiten mit Abschlusspräsentationen
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Teaching Times: Full-timeMonday to Friday from 8:30 a.m. to 3:35 p.m. (in weeks with public holidays from 8:30 a.m. to 5:10 p.m.)
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Language of Instruction: German
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Duration: 20 Weeks
PLC: Working with Simatic S7 in the TIA Portal
System overview (approx. 2 days)
Course objective, course sequence, teaching concept
Key features of the SIMATIC S7 system family
Components of the TIA portal, STEP 7
Hardware (approx. 2 days)
Design and assembly of the automation system
Display and operating elements of the SIMATIC CPU
Addressing and wiring the signal modules
Device configuration in the TIA Portal
Artificial intelligence (AI) in the work process
Presentation of specific AI technologies
and possible applications in the professional environment
Program (approx. 14 days)
Program processing by the control system
Program test with PLCSIM
Binary operations in FBD LAD IL
Time steps, counters, comparators, accumulator operations
Use of the various block types (OB, FC, FB, DB), program structuring
Data management with data blocks
FB as multi-instance
IEC-compliant blocks
Explanation and use of various organizational blocks
Program language SCL
Project handling (approx. 2 days)
Archiving and migrating projects
Using reference projects
Working with libraries
Converting S7-300 projects to the S7-1500 system
Step chain programming (approx. 5 days)
Step chain representation according to DIN 60848 (Graphcet)
Step chains in FBD
Presentation of sequence control with S7-Graph
Working with S7-Graph
Commissioning and diagnostics/working with the hardware (approx. 5 days)
Establishing a connection to a real CPU
Test tools for system information, troubleshooting and diagnostics
Recognizing and rectifying basic hardware faults
Hardware diagnostic functions of the TIA portal
Software diagnostic functions of the TIA portal
Commissioning a TIA system with software troubleshooting and fault rectification
Analog values (approx. 2 days)
Principle of analog value processing in the SIMATIC S7
Configuring the connection of analog sensors
Evaluating analog measured values in STEP 7
Output of analog values
Updating and documenting projects (approx. 1 day)
Save and document program changes made
TIA Portal tools for documentation
Project work (approx. 5 days)
To consolidate the content learned
Presentation of the project results
PLC: Visualization, process data processing with WinCC and networking in the TIA Portal
PROFIBUS (approx. 2 days)
Hardware overview of PROFIBUS devices, bus parameters
Communication principle
Setting up PROFIBUS networks between SIMATIC CPU and various DP devices
PROFINET I/O (approx. 2 days)
Basics, IP addresses
Hardware overview of PROFINET devices
Setting up PROFINET networks between different components
WinCC basics (approx. 1 day)
Presentation of the working environment
Usable hardware and initial project creation
Creating and managing an HMI project
Creating a project with the wizard
Artificial intelligence (AI) in the work process
Presentation of specific AI technologies
and possible applications in the professional environment
HMI project planning with WinCC in the TIA Portal (approx. 5 days)
Creating visualization screens, navigating between several screens, using templates
Using internal and external variables, animating WINCC objects
Displaying values of PLC variables (I/O field, bar, pointer instrument)
Use symbol library object for display and operation
Using text and graphics lists
Extended functions for HMI (approx. 4 days)
Creating user keys and assigning authorizations
Entering and displaying messages
Working with recipes
Plan tasks, record process data
Commissioning and use of an HMI device (approx. 1 day)
Project work (approx. 5 days)
To consolidate the content learned
Presentation of the project results
Electrical planning with EPLAN
EPLAN Basics (approx. 1 day)
Setting up the user interface
Create and manage projects
Define project and user settings
Backing up and restoring projects
Artificial intelligence (AI) in the work process
Presentation of specific AI technologies
and possible applications in the professional environment
Graphic editing (approx. 8 days)
Create project pages, edit page properties
Creating circuit diagrams, symbol and device-oriented
Using symbols and macros
Creating and dimensioning overview drawings
Using navigators when working with circuit diagrams
Managing EPLAN (approx. 6 days)
Creating and managing symbols and macros
Editing and creating standard sheets and forms
Creating devices and customers in the database
Evaluating circuit diagrams (approx. 3 days)
Creating terminal and cable diagrams
Automatically output parts lists and legends
Create cover sheets and integrate graphics
Project work (approx. 2 days)
To consolidate the content learned
Presentation of the project results
Electromobility
Introduction to electromobility (approx. 1 day)
Energy efficiency compared to combustion engines
Effects of the mobility transition
Potential and prejudices of e-mobility
Current market situation
Basics of the electric vehicle (approx. 2 days)
Electric vehicles, hybrid and plug-in hybrids, electric cargo vehicles
Design and functionality of electric vehicles
Drive and electric mobility concepts
Energy and storage technology
Grid integration (smart charging, vehicle-to-grid)
Electrified drive train (approx. 3 days)
Basics of electric motors: Requirements, types (direct current, three-phase current, permanent magnet, induction)
Operation in electric vehicles
Calculation principles for electric car drives
Battery technologies (types, capacities, service life, battery management, safety aspects, raw material problems, recycling strategies)
Artificial intelligence (AI) in the work process
Presentation of specific AI technologies
and possible applications in the professional environment
Power electronics for electric vehicles (approx. 3 days)
Areas of application and requirements (inverters, DC/DC converters)
Components (SiC, GaN semiconductors, IGBTs)
Measuring equipment and test procedures
Basic structures and
Circuit topologies and control concepts
Electromagnetic compatibility (EMC)
Functional safety for automotive (approx. 1 day)
Current legislation and standards (ISO 26262)
Safety life cycle in vehicle construction
Safety-relevant functions and their planning
Development of safety concepts in different roles
Charging and charging infrastructure (approx. 2 days)
Charging rate, charging modes, charging times, charging locations
Inductive charging and fast charging (e.g. CCS)
Grid integration: power grids, load management, grid-side requirements
Current situation of the charging infrastructure in Germany
Profitability and business models (e.g. charging flat rates, sharing)
Range and consumption of electric vehicles (approx. 1 day)
Physical basics (energy consumption, efficiency)
Driving cycle methods: NEDC, WLTP, real consumption
Calculation of consumption and range
Electricity for the electric vehicles (approx. 1 day)
Energy generation: Renewable energies, electricity mix in Germany
Electricity storage technologies (Power-to-X, pumped storage, battery storage)
Life cycle assessment of electric vehicles (approx. 1 day)
Assessment of an environmental balance sheet
Production, use and recycling
Sustainability aspects
Business models and legal aspects (approx. 1 day)
Charging station ordinance
Electricity Tax Act/EEG
DGUV regulations
EU Battery Ordinance
Subsidies and funding programs
Car Policy E-vehicles
Future prospects and technologies (approx. 1 day)
Market ramp-up
Mobility 2050
Hydrogen, fuel cells, synthetic fuels
Project work (approx. 3 days)
To consolidate the content learned
Presentation of the project results
Changes are possible. The course content is updated regularly.
After this course, you will understand the interaction of the TIA components. You will be able to modify and adapt existing STEP 7 programs and systematically diagnose and rectify hardware and software faults in a simple TIA system.
You will also know how to operate WinCC in the TIA Portal efficiently and safely, edit WinCC projects for machine-related use and design graphic images. You will also be able to set up and configure industrial networking at fieldbus level with PROFIBUS-DP and the Industrial Ethernet standard PROFINET I/O.
You will also learn how to use the new EPLAN drawing environment. This includes the drawing of circuit diagrams in the areas of device, machine, plant and building technology. After the course, you will also be able to evaluate these plans and document electrical systems and devices.
After completing this course, you will also have in-depth knowledge of electromobility, its technical foundations, current developments and legal framework conditions. You will be able to assess the possible applications of various drive systems and understand the challenges and opportunities of the mobility transition. You will also be able to plan and present practical projects in the field of electromobility.
People with a degree in engineering, electrical engineers, automation specialists, mechatronics engineers, technicians, master craftsmen and specialists with relevant professional experience.
Your meaningful certificate provides a detailed insight into the qualifications you have acquired and improves your career prospects.
Didactic concept
Your lecturers are highly qualified both professionally and didactically and will teach you from the first to the last day (no self-study system).
You will learn in effective small groups. The courses usually consist of 6 to 25 participants. The general lessons are supplemented by numerous practical exercises in all course modules. The practice phase is an important part of the course, as it is during this time that you process what you have just learned and gain confidence and routine in its application. The final section of the course involves a project, a case study or a final exam.
Virtual classroom alfaview®
Lessons take place using modern alfaview® video technology - either from the comfort of your own home or at our premises at Bildungszentrum. The entire course can see each other face-to-face via alfaview®, communicate with each other in lip-sync voice quality and work on joint projects. Of course, you can also see and talk to your connected trainers live at any time and you will be taught by your lecturers in real time for the entire duration of the course. The lessons are not e-learning, but real live face-to-face lessons via video technology.
The courses at alfatraining are funded by Agentur für Arbeit and are certified in accordance with the AZAV approval regulation. When submitting a Bildungsgutscheinor Aktivierungs- und Vermittlungsgutschein, the entire course costs are usually covered by your funding body.
Funding is also possible via Europäischen Sozialfonds (ESF), Deutsche Rentenversicherung (DRV) or regional funding programs. As a regular soldier, you have the option of attending further training courses via Berufsförderungsdienst (BFD). Companies can also have their employees qualified via funding from Agentur für Arbeit (Qualifizierungschancengesetz).