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- 2.- ÉLECTRONIQUE
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- 4.- ÉLECTRICITÉ
- 5.- ÉNERGIE
- 5.1.- RÉSEAUX INTELLIGENTS ET SYSTÈMES D'ALIMENTATION
- 5.2.- MICRORÉSEAUX
- 5.3.- ÉNERGIES RENOUVELABLES
- 5.3.1.- ENERGIE SOLAIRE PHOTOVOLTAÏQUE
- 5.3.2.- ÉNERGIE SOLAIRE THERMIQUE
- 5.3.3.- ÉNERGIE ÉOLIENNE
- 5.3.4.- ENERGIE MARINE
- 5.3.5.- ÉNERGIE GÉOTHERMIQUE
- 5.3.6.- ÉNERGIE HYDRAULIQUE
- 5.3.7.- BIOCARBURANTS
- 5.3.8.- SYSTÈMES D'ACCUMULATION
- 5.3.9.- PILES À COMBUSTIBLE HYDROGÈNE
- 5.3.10.- TURBINES À VAPEUR ET CYCLES ORGANIQUES RANKINE
- 5.3.11.- AUTRES SYSTÈMES NON CONVENTIONNELS
- 5.4.- ÉNERGIES CONVENTIONNELLES
- 5.5.- STOCKAGE DE L'ÉNERGIE
- 5.6.- SYSTÈMES DE PROTECTION ÉLECTRIQUE ET HAUTE TENSION
- 5.7.- INSTALLATIONS ET MAINTENANCE
- 6.- MÉCATRONIQUE ET AUTOMATISME
- 7.- MÉCANIQUE
- 8.- MÉCANIQUE DES FLUIDES
- 9.- THERMODYNAMIQUE ET THERMOTECHNIQUE
- 9.1.- FONDEMENTS ET CONCEPTS FONDAMENTAUX DE LA THERMODYNAMIQUE
- 9.2.- CHAUFFAGE, VENTILATION, CLIMATISATION ET EAU CHAUDE
- 9.3.- POMPES À CHALEUR
- 9.4.- RÉFRIGÉRATION
- 9.5.- SYSTÈME DE TUYAUTERIE HYDRAULIQUE THERMIQUE
- 9.6.- TRANSFERT DE CHALEUR
- 9.7.- ÉCHANGEURS DE CHALEUR
- 9.8.- MACHINES THERMIQUES
- 9.9.- MOTEURS À COMBUSTION INTERNE
- 9.10.- INSTALLATIONS ET MAINTENANCE
- 10.- CONTRÔLE DE PROCESSUS
- 11.- INGÉNIERIE CHIMIQUE
- 11.1.- UNITÉ D'OPÉRATIONS
- 11.1.1.- FLUIDISATION
- 11.1.2.- ÉVAPORATION
- 11.1.3.- ÉBULLITION
- 11.1.4.- DISTILLATION ET FISSURATION
- 11.1.5.- EXTRACTION
- 11.1.6.- DIFFUSION
- 11.1.7.- SÉCHAGE ET REFROIDISSEMENT
- 11.1.8.- ABSORPTION ET ADSORPTION
- 11.1.9.- ECHANGE D'IONS ET CORROSION
- 11.1.10.- CRISTALLISATION ET PYROLYSE
- 11.1.11.- FILTRATION, SÉDIMENTATION ET MÉLANGE
- 11.1.12.- TRAITEMENT DES SOLIDES
- 11.2.- REACTEURS CHIMIQUES
- 11.1.- UNITÉ D'OPÉRATIONS
- 12.- TECHNOLOGIE DE L'EAU ET DES ALIMENTS
- 13.- ENVIRONNEMENT
- 14.- GÉNIE BIOMÉDICAL
- 14.1.- BIOMECANIQUE
- 14.1.1.- PRINCIPES DE BASE MÉCANIQUE
- 14.1.2.- MACHINES SIMPLES
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- 14.1.7.- PHOTOÉLASTICITÉ ET MESURE DE DÉFORMATION
- 14.1.8.- ESSAIS MÉCANIQUES
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- 14.2.- ÉLECTRONIQUE BIOMÉDICAL
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Génie chimique et ses processus
What is chemical engineering?
Importance of chemical energy in today's industry.
Chemical energy drives countless industries around the world. From plastics production to electricity generation, chemical engineering plays an essential role in optimizing these processes to maximize efficiency and minimize environmental impact.
Chemical reactors:
Chemical reactors are the heart of chemical engineering, where chemical reactions transform raw materials into desired products. Their characteristics vary from the type of reaction they support to how they control temperature and pressure to ensure optimal results.
Types of processes – what they are and their characteristics:
Fluidization:
Fluidization is a key phenomenon in chemical engineering, where solids are turned into a fluid by introducing a gas. This process is essential in handling solid particles in industries such as pharmaceuticals and food.
Evaporation and boiling:
Evaporation and boiling are fundamental processes in separating liquid components from a mixture. Understanding their characteristics is essential for designing efficient and economical distillation systems.
Distillation and cracking:
Distillation, known for separating liquid components through evaporation and condensation, joins cracking, a process that breaks complex molecules into simpler components. These processes are crucial in the production of fuels and chemicals.
Extraction:
Extraction involves separating soluble components using solvents. Its characteristics vary depending on the nature of the materials to be extracted, being essential in the production of essential oils and pharmaceuticals.
Diffusion:
Diffusion is the movement of molecules from an area of higher concentration to one of lower concentration. This process is vital in optimizing mass transfer in systems such as chemical reactors.
Drying and cooling:
Drying and cooling are fundamental processes in the food and pharmaceutical industries. Understanding their characteristics is essential to ensure the quality and stability of heat-sensitive products.
Absorption and adsorption:
Absorption and adsorption are processes that involve retaining molecules on a surface. These processes are crucial in purifying gases and liquids in industrial applications.
Ionic exchange and corrosion:
Ionic exchange is essential in water purification, while corrosion poses a constant challenge in chemical engineering. Understanding these characteristics is crucial to ensure equipment integrity and product quality.
Crystallization and pyrolysis:
Crystallization is a key process in producing pure solid products, while pyrolysis involves the thermal decomposition of organic materials. Both processes have diverse applications in chemical engineering.
Filtration, sedimentation, and mixing:
Filtration and sedimentation are solid-liquid separation processes, while mixing is essential in homogenizing mixtures. These processes are fundamental in the production of chemicals and pharmaceuticals.
Solid treatment:
Solid treatment involves processes such as crushing and granulation to improve the handling and storage of solids. These processes are essential in the production of fertilizers and pharmaceuticals.
Why is it important to have absolute control and clear training in the practice of all chemical engineering processes?
Precise process control and clear training are crucial in chemical engineering to ensure safety, efficiency, and product quality. A small error can have significant consequences, highlighting the importance of continuous training and rigorous control.
Prominent equipment in the field of chemical engineering.
With extensive experience in research and collaboration with professionals and researchers in the field of chemical engineering, EDIBON presents training and research equipment designed to enrich the educational process and contribute significantly to research in this area. Our wide range includes specific equipment for chemical engineering, such as the Fixed and Fluidized Bed Computer-Controlled (PC) Equipment (LFFC), the Rising Film Evaporator Computer-Controlled (PC) ("EPAC"), the Batch Distillation Equipment Computer-Controlled (PC) ("UDDC"), and the Chemical Reactors Training System Computer-Controlled (PC) (QRQC). These advanced products offer practical and visual experiences, strengthening the understanding of theoretical concepts and fostering excellence in chemical engineering and academic research.
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In conclusion, chemical engineering is a multidisciplinary field that drives the efficient and sustainable production of a wide range of products. From chemical energy to various transformation processes, this area plays a central role in the evolution of modern industry. With absolute control and clear training, chemical engineers continue to be architects of a more sustainable and prosperous future.