Projects

IRIS

Description:

The Integration of Real time simulation on FPGA components or IRIS project is the joint effort of EPM laboratory and SPHEREA Test and Service company aimed to develop a new real time simulation system for power electronics and electrical machines based on a custom fast computational hardware implemented in Field Programmable Gate Arrays.

The product testing and maintenance is an important part of its life cycle in the industries with high security and quality demands such as aerospace, transportation or energy production. It allows reducing the risks of accidents, prevents financial losses due to systems failures in energy production and to increase safety. The testing can be very costly for big and complex systems such as an airplane or an electrical station but, although necessary, it can be replaced by a real time simulation at the first stage of the controllers and subsystems verification. In some cases, the testing on the real hardware can be even impossible if a response to faulty conditions is to be checked. The hardware in the loop simulation allows carrying out integral tests of the control systems and independent subsystems without connecting to the actual real-world equipment to greatly reduce the costs and damage risks.

The conventional HIL simulation systems doesn’t allow real time simulation of systems with very fats dynamics such as electrical power systems and machines. The IRIS project is centered around solving the dynamics equation of electrical systems and its acceleration with FPGA/System on Chip. Currently it includes the solvers for generic linear electrical systems based and power electronics the augmented nodal method, and synchronous electrical machines based on state space modeling, but additional type of solvers are planned to be developed. For both these methods a lot of computational power is required if fast real time dynamics simulation is to be achieved. Form the other point of view, the real-time simulation requirements impose the constraints on the loopback response latency. 

To respect these constraints the IRIS project uses hardware computation acceleration and input outputs control base on FPGAs – electronic components allowing to build reconfigurable digital logic circuits. Compared to conventional microprocessors they provide much larger flexibility and optimization of computation pipelines and compared to such devices as GPU they allow hard real time determinism insuring that a proper signal will be sent in the proper place and at the correct time which is very important for the communication with tested equipment and controllers. 

The IRIS simulation system has a modular architecture with asynchronous simulation modules designed for the specific electrical system simulation. The simulation modules are controlled and configured from the system on chip with an ARM core which is also used for host PC communication. This allows online configuration and reconfiguration on the fly to treat non-linearities and slow dynamics that can also be simulated on software part. 

The solvers developed in the IRIS project can be used for simulation of electrical power systems for the first stage testing and verification. It can be applied for testing and verification of power production, onboard power grids, electric propulsion and mechatronics in aerospace, automotive, railroad and power production industries. If you are interested in getting more information about the IRIS project or how you can apply it to solve your tasks, feel free to contact us at the contact information given below.

Partners:

  • L2EP, EPMLab
  • SPHEREA Test and Service
    • 5 Avenue Georges Guynemer CS70086 31772 Colomiers Cedex, France

By Frédéric Colas, ago

CE2I – Convertisseur d’Energie Intégré Intelligent

Identification: “Control Strategies of a DC Based Offshore Wind Farm With Series Connected Collection Grid”

Aims:

  • Propose control strategy for a new topology of off shore wind farms
  • Build a laboratory test bench for testing the control
  • Main characteristics of the test bench:
    • Vdc = 400V ; Vg = 220V at 50Hz ; Prated = 5kW
    • Central coordination of wind turbine emulation
    • Use of DC cable
Experimental Test Bench

Period: from October 2016 to December 2017

Sponsors: The Nord Pas de Calais’ Council, the French State, European Union

Context: HVDC to HVAC Conversion ; Offshore wind farms; HVDC transmission

Main results:

  • Development and verification of an innovative control strategy
  • Use of real time simulation for the power converter control
  • Experimental results of a small scale wind farm
  Figure 2DC Power Supplies Figure 3 Electric cabinet
 Figure 4 VSC CINERGIA

Partners:

  • Partner n ° 1 :   Hautes Etudes d’ingénieur –  13 Rue de Toul, 59000 Lille (France)
  • Partner n ° 2:   Arts et Métiers ParisTech – 8, Boulevard Louis XIV – 59000 LILLE (France)
By francois.gruson@ensam.eu, ago

MTDC Experimental Grid

Identification:  “Multi-Terminal DC grid mock-up for off-shore energy production”

Description: 

  • Main Topic : control of MTDC grids
  • Aims: DC voltage and AC frequency control

The growth of offshore wind farms and their geographical dispersion will perhaps lead to a multi-terminal DC (MTDC) configuration. The control strategies of DC system should consider both DC voltage constraints and frequency support of interconnected AC grids.

In the different stages of development for technological applications, the low scale demonstrator is a very important validation phase after the theoretical simulation analysis and prior to first prototypes or industrial installations. In terms of development of MTDC grids, it could still last for many years before getting the first on-site high voltage demonstrator, mainly due to the huge costs involved in such projects and to their impact on the operation of exiting grids. Therefore, the mock-up developed in TWENTIES demo3 provides an interesting intermediate and flexible step between simulations and on site demonstrator by mixing reduced power DC links and real-time simulation to develop an actual low power MTDC grid. This DC grid can be interconnected to a virtual AC power system.

Single-line diagram of the MTDC mock-up

Sponsor:

  • RTE

Main results: 

  • Validation of dual droop control technique on three terminal configuration
  • Validation of MPC control

Partners:

  • Partner n ° 1 (Pilot): Laboratoire L2EP in Lille / Arts et Métiers ParisTech – Lille – Address : 8, Boulevard Louis XIV – 59000 LILLE (France)
  • Partner n ° 2 : Laboratoire L2EP in Lille / Ecole centrale de Lille – Address:  Cité Scientifique, 59651 Villeneuve-d’Ascq (France)
  • Partner n ° 3 : RTE-France – Address:  CNER / Département Postes, Cœur Défense 100, Esplanade Charles de Gaulle F-92932 Paris La Défense (France)
By Frédéric Colas, ago

MMC prototype

Project Name:                                                        Do-MMC

Identification:“Design of Modular Multilevel Converter for DC grid”

Description or Abstract:

  • Aims:
    • Develop a Lab prototype of Modular Multilevel Converter (MMC)
    • The prototype must be as closest as possible to the full scale transmission grid MMC
  • Main characteristics:
    • Vdc= 400V ; Vg= 116V at 50Hz ; Prated= 5kW ; Qrated= 1,5kVAR
    • 20 Sub-modules by arm
MMC schematic
  • Period: from October 2014 to December 2016
  • Sponsors: The Nord Pas de Calais’ Council, the French State, Cinergia (Spanish Power Electronics Company) and RTE (French TSO)
  • Context:HVAC to HVDC Conversion ; Transmission Power System
  • Main results:
    • Develop a control architecture of a MMC with lots of switches (240 switches)
    • Use the real time simulation as an aid in the control of complex converters.
    • Produce experimental results of the MMC advance control method proposed by the team
    • Produce two copy of the prototype in order to propose a point-to-point link
By francois.gruson@ensam.eu, ago

OUEST 2020

Identification:  “Energy and social optimization of a tertiary campus on the horizon 2020”

Aims:

  • Improve the Energy consumption ‘Management of The Campus Pasteur Lille
  • Develop real time models of renewable sources systems to secure and save consumption of the Campus
  • Integration of human behavior on energy to download the consumptions
Project logo
Mascot Pasteur

Period: from September 2013 to December 2015 (24 months)

Sponsors:  Nord-Pas-de-Calais Regional Council 

Context:   European Environmental rules “3 X 20″and French Regulation called “The GRENELLE”

Main results: 

  • Local Energy production implanted on the Campus: CHP, VOSS and Photovoltaics = 530 kWe
  • Best-case Scenario demonstrate a reduction of greenhouse effects gas : 24% in 2022
  • Creation of a group of users referents for the learning of eco-friendly gestures: Initiative Eco-Campus

Partners:

  • Partner n ° 1 (Pilot): Engineering School “Arts et Métiers Campus” in Lille (France): 8, Boulevard Louis XIV – 59000 LILLE (France)
  • Partner n ° 2: Explorateur de la Transition: Social and Humain behavior Laboratory “Lille catholic University ‘: – 59000 LILLE (France)
  • Partner n ° 3 : Pasteur Lille Foundation: 1, Rue de Professeur  Calmette – 59000 LILLE (France)
By Frédéric Colas, ago

ZAC St Sauveur

Identification:  “Dynamic Modelling of a multi-energy grid for the setting-up of a new district named  “Zac Saint Sauveur” in the city of Lille”

Aims:

  • Improve the Energy exchange between different type of grids ( heat, gas and Electricity, …)
  • Develop real time models of renewable sources and storage systems to cover the major part of the consumption on this district
  • Integrate consumptions of new buildings following “Energy+ & Carbon-“rules.
  • Help the MEL and his partners to improve the construction of the new district.
  • Work in interaction with a many partners to co-elaborate this new district
Area of 23 ha ; about 280 000 m² Shon: ZAC St SAUVEUR, building projection (view 2015)

Lasting: from September 2016 to September 2018 (24 months)

Supporters: The European Metropolis of Lille (the MEL) and Funding “EcoCités”

Context: European Environmental rules “3 X 20“ and the French Energy transition’s laws

Main results in progress:

  • About 24 GWh per year of energy mix in 2030
  • Development of Locals Renewables Energies sources and storages: CHP, Photovoltaics, solar thermal system , Management of electrical vehicles refilling, New district heating loops
  • Best-case Scenarios thought to bring reduction of greenhouse gas and cost of kWh.
  • Simulations (hourly time) during 2 representative weeks: one in summer and one in winter following the construction planning.
  • Mix of the 3 different energy grids to decrease GhG[1] effects

Partners, Collaborative project with 7 organizations

  • MEL : Métropole Européenne de Lille
  • Ville de Lille
  • GRDF 
  • Enedis
  • Résonor
  • Arts et Métiers ParisTech

[1] Greenhouse Gases : gases who have an effect on the Environment

By Frédéric Colas, ago