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| Trainings by domains |
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| Trainings by Technology |
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| Trainings by jobs |
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Take a look : Instrumentation and control |
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Instrumentation handling and wiring |
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CRI |
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Perform the wiring of measuring, detection and control devices.
Troubleshoot the main dysfunctions related to wiring.
Perform loop synchronization.
Handling an installation instrumentation wiring. |
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Engineering department |
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BE1 |
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> Know the engineering department functions
> Choose instrumentation and control devices adapted to a process
> Define technical specifications
> Evaluate control devices |
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Instrumentation for engineering departments |
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BE1I |
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> Choose instrumentation
> Define technical specifications
> Know the main standards used in instrumentation |
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Control for engineering departments |
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BE1R |
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> Design control strategies adapted to a process.
> To be able to communicate with manufacturers and technical staff.
> Evaluate control devices. |
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Heating - Conditioning |
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CLIM |
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> Address design and setup problems
> Learn necessary physical basics for understanding and maintenance. |
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ATEX Renewal |
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RECYCL_ATEX |
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Renew ISM-ATEX levels 1 or 2 certification |
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Instrumentation Field Buses |
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RTI |
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> Know the principles and characteristics of instrumentation field buses.
> Understand the contributions and limits of field buses.
> Choose the field bus adapted to your needs.
> Setup and tune fundamental parameters. |
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Safety automation integrity - Machine control safety |
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SIL-SCC |
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> Bring qualitative and quantitative proof of the SIL level conformity and performance level.
> Understand the rules and standards evolution regarding machines and process safety.
> Know the pros and cons of different techniques and architectures.
> Design; install and maintain safety automated systems on machines by following an approach and methodology respecting rules and standards.
> To be able to integrate sensors, safety controllers, actuators with respect of the requested safety integrity level (SIL) and performance level. |
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Control symbolization |
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SYMBOL |
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Understand piping and instrumentation diagrams.
To be able to design diagrams (P&ID, PFD) |
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Process Control Technique |
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TRP |
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> To be able to design or improve industrial control loops.
> Understand the most used control principles in industrial processes. |
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Control Valves |
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V |
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> To be able to define, choose and calculate control valves
> Determine valve malfunctions and possible solutions
> Improve process control |
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Setup and maintenance of wireless networks |
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WLAN |
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> Understand the operation principles of wireless networks, protocols and network architectures.
> Understand the wireless components and operational specifications.
> Setup and maintain Ethernet wireless networks (802.11a/b/g). |
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Explosive atmospheres for construction managers |
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ATEX 2 |
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> Welcome, train and follow employees working in explosive atmospheres zones.
> Warrant the respect of maintenance intervention rules.
> Choose adapted instrumentation and control devices for explosive atmospheres.
> Master principles of intrinsic safety as well as loop calculations.
> Warrant interventions traceability. |
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Automation project on batching processes |
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BATCH |
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> To be able to design the automation of a batching process with a digital controller (DCS, PLC or other) |
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Project in Instrumentation and Control |
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BE2 |
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> At the end of this training, participants will have studied the different phases of specification, design and implementation of an automated continuous process project. |
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Safety Instrumented Systems - Quali-SIL |
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SIS |
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> Understand risk analysis regarding the IEC 61511, IEC 61508 standards and regulations.
> Define an architecture and validate it according to the required SIL.
> Know the calculation methods of reliability and availability used to defiine the obtained SIL (quantitative requirements).
> Make sure the required SIL is maintained during maintenance.
> Know the requirements of the 61 511 standard and incorporate the SIS.
> Obtain the Quali-SIL certification |
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Industrial Measures Technique |
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TM |
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> Perfecting measuring techniques
> Account the metrological aspect
> Know the limits and influence factors of industrial measures
> Perform calculations relative to flow (normalized flow) |
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Take a look : Metrology and measure |
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Metrology from A to Z |
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MET |
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Know metrological needs.
Understand ISO calculations on uncertainty.
Master instrument's maximum permissible measurement error.
Organize a metrology function following quality referentials (ISO 9000 version 2000, ISO TS, BPF, FDA, ...).
Daily management of an efficient metrological function adapted to a business. |
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Metrology - Introduction and uncertainty calculations |
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MET1 |
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> Know metrological needs.
> Understand and calculate uncertainty following ISO standards.
> Master maximum permissible measurement errors on instruments. |
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Implementation of a metrological function |
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MET2 |
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> Organize a metrological function according to quality requirements (ISO 9000 version 2000, ISO TS, BPF, FDA, ...).
> Manage daily an efficient metrological function adapted to a business. |
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Metrology Perfectionning |
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MET+ |
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Perfect uncertainty calculations.
Validate knowledge and skill acquired in MET1 and MET2 trainings.
Acquire reflexes and methods for the implementation and editing of uncertainty calculations.
Live an experience of an "auditor" and "auditee" in metrology.
To be able to present the metrological function in an audit phase.
Review and put to practice acquired experiences. |
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Liquids totalization |
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MICLIQ |
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> Perfect techniques for liquid totalization. |
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Take a look : Advanced control |
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Fuzzy logic and process control |
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FLOU |
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> Know the basic principles of fuzzy logic.
> Show the control benefits of this tool. |
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Advanced control through practice |
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CA |
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> Acquire a synthetical and comparative vision of advanced control.
> Understand the technical and economical benefit of advanced control over PID control.
> Know the principle of the most used advanced control tools in the industry. |
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Multivariable process control |
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RPM |
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> Acquire a methodology to analyse interactive control loops problems.
> Learn and measure the benefits of model predictive control applied to multivariable processes. |
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Take a look : Online analysis |
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Water management basics |
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BGE |
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> Discover the physical and psycho-chemical properties of water
> Acquire basics on characterization methods of quality.
> Understand the principles of treatment to adapt its quality to its usage.
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Industrial Analysers Overview |
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PAI |
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> Discover the online industrial analysers principles.
> Learn on the different technologies and possibilities.
> Be aware of the sampling importance.
> Acquire specific vocabulary.
> Help on choosing equipments. |
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Practice of Applied Statistics on Measures - QAL 3 |
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PSM |
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> Learn the vocabulary used in statistics.
> Evaluate equipment performances or a method.
> Know how to use the statistical tools to:
- Establish a control sheet
- Interpret a control sheet |
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Water sensors and analysers usage |
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ECA |
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> Discover the applicable metrology on water measurements, setup rules and applicable standards.
> Learn an equipment buying method.
> Be aware of exploitation procedures and equipment maintenance.
> Give the basics for organizing a measurement service. |
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Sampling Systems for Industrial Analysers |
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SEA |
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> Understand the structures of sampling systems.
> Perfect the knowledge of their elements.
> Calculate pressure drops and response times in a transfer line.
> Acquire the elements to design or modify a sampling system. |
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Sequential systems functional analysis |
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SFC |
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> Describe and break down automation with the SFC language.
> Translate specifications and write a functional analysis with a sequential command graph.
> Describe the running and stopping modes of an installation. |
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Operation systems |
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SNCC-API |
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> In a project, define the elements to choose between a programmable logic controller (PLC) and a distributed control system (DCS) by associating alarm management, safety aspects (SIL), networks, MES, Batch, ...
> Participate in the setup of 4 automated systems. |
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Communication Networks Architecture |
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ARC |
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> Understand the components of industrial networks (standards, protocols, architectures, ...)
> Master the characteristics and principles of networks, from the field to the plant.
> Improve communications between the technical staff and the manufacturers. |
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Management of Automation projects and software life cycle |
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GPA |
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> Acquire tools and methods to manage particularities of an automated industrial project.
> Realize specifications for an automated industrial project.
> Understand and setup a software life cycle.
> Realize a functional and organic analysis of an automated system for a programmer.
> Identify and plan tasks. |
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HMI - Supervision and operator interface |
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AUT4 |
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> Specify and design HMIs (Human - Machine Interface) with ergonomic rules, characteristics and operator needs.
> Manage efficiently communications between a PLC and an HMI.
> Install, configure, program and setup an HMI or a supervision. |
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