fluidyn-VENTCLIM Fluidyn-VENTIL-VENTCLIMFluidyn-VENTIL-VENTCLIM For Ventilation, Smoke evacuation and Air – conditioning Modelling - VENTCLIM fluidyn-VENTCLIM
Application Domains 3D Modeling tool 3D Modeling tool Simulation of internal flows Simulation of internal flows Sanitary ventilation (estimation of Sanitary ventilation (estimation of pollutant concentrations ) pollutant concentrations ) Emergency ventilation in fire situations Emergency ventilation in fire situations
fluidyn-VENTCLIM Physical and Numerical Models Conduction – convection - radiation Conduction – convection - radiation Navier-Stokes equations Navier-Stokes equations Finite volumes method Finite volumes method Turbulence models (k-l, k-, …) Turbulence models (k-l, k-, …) Two-phase flows: Two-phase flows: lagrangian model (particles, droplets, …) lagrangian model (particles, droplets, …) evaporation, break-up, coalescence evaporation, break-up, coalescence Pollutant sources Pollutant sources
fluidyn-VENTCLIM ResultsResults 3D fields (pressure, temperature, 3D fields (pressure, temperature, hygrometry, species concentration, …) hygrometry, species concentration, …) Velocity vectors Velocity vectors Iso-surface (pollutant concentration, Iso-surface (pollutant concentration, temperature, …) temperature, …)
fluidyn-VENTCLIM Geometry creation (1) Available geometry elements: Domain Enclosure Partition Walls Arbitrary Obstacles Cylindrical Obstacles Pipe along X-axis Pipe along Y-axis Regular opening Irregular opening Extractor Monitor point Altitude contours Actions possibles
fluidyn-VENTCLIM Geometry creation (2)
fluidyn-VENTCLIM 3D view of the geometry
fluidyn-VENTCLIM Pollutant sources (1) Sources: point general surface Filters: cylindrical box Possible actions
fluidyn-VENTCLIM Pollutant sources (2) Pollutant source parameters Pollutants released Mass flow rate Temperature Instant of release Release duration
fluidyn-VENTCLIM Boundary conditions Conditions inside the domain Conditions outside the domain Parameters : Humidity rate Temperature
fluidyn-VENTCLIM Mesh generation parameters Mesh refining parameters Select: Uniform / non-uniform Select: Manual control / auto Control parameters
fluidyn-VENTCLIM Example of results
fluidyn-VENTCLIM Fluidyn-VENTIL: Mesh Generation using GUI 1D-3D coupling & pre-meshed entities
fluidyn-VENTCLIM Ventilation duct modeling 1.Line mode (1D computational mesh) For extensive network 2. 3D mode computational mesh for detailed local geometry 3. 3D-1D Hybrid mode for combining the two
fluidyn-VENTCLIM Characteristics of the three modes in Fluidyn-VENTIL: 1D MODE for ventilation network Flow is one-dimensional with effects of the wall roughness Suitable in regions away from intersections and flow re-circulation zones. Computationally least expensive, but 2D and 3D effects such as boundary layers and flow turnings not properly resolved. 3D MODE for local complex geometries Full 3D flow. Most accurate, however, computationally more expensive. 3D-1D HYBRID MODE 3D-1D coupled flow. Proper interpolation at 3D-1D mesh interface. Computationally economical than full 3D. Ventilation ducts modelling
fluidyn-VENTCLIM 1D mesh 3D Unstructured mesh
fluidyn-VENTCLIM Geometry Features Sub – options for tracing and modifying the Geometry Features Sub – options for tunnel/ducts GUI for Geometry Definition
fluidyn-VENTCLIM Mine Shafts Tunnels, ducts 3-D 1-D 3-D Case Setup
fluidyn-VENTCLIM Input data for Geometry GUI for Geometry Data
fluidyn-VENTCLIM Menu options for ‘Fluid Data Base’ List of Fluid Fluid Database Menu
fluidyn-VENTCLIM Tunnel connectivity using Sphere Attachment of ducts with shafts or major conduits 3D mesh 1D mesh Meshing of network – 1D & 3-D
fluidyn-VENTCLIM Spherical Connection between ducts
fluidyn-VENTCLIM Connection between shaft and ducts
fluidyn-VENTCLIM Connection between shaft and ducts Grid and contour option
fluidyn-VENTCLIM A Case Study Ventilation and fire in a train compartment A Case Study Ventilation and fire in a train compartment
fluidyn-VENTCLIM 2 phases : Experimental validation: fire simulation in confined Experimental validation: fire simulation in confined spaces spaces Test experiments: test compartment with seats and Test experiments: test compartment with seats and ventilation system ventilation system comparison of simulation results with comparison of simulation results with experimental results experimental results Simulation of an entire wagon Simulation of an entire wagon complex geometries complex geometries multiple boundary conditions multiple boundary conditions ventilation system ventilation system Fire in a train compartment
fluidyn-VENTCLIM Case presentation Entry B Entry A Exit B Exit A
fluidyn-VENTCLIM Location of monitor pointsComparison with experiment Comparison with experiments
fluidyn-VENTCLIM Geometry and boundary conditions Entire wagon : boundary conditions
fluidyn-VENTCLIM Velocity vectors : transverse section
fluidyn-VENTCLIM Temperature fields
fluidyn-VENTCLIM A Case Study Ventilation in a nuclear building A Case Study Ventilation in a nuclear building
fluidyn-VENTCLIM Ventilation in a nuclear building Study specifications: Ventilation study in a building of around 1000 m 3 Ventilation study in a building of around 1000 m 3 Installations distributed in 2 floors and a dome on the roof Installations distributed in 2 floors and a dome on the roof Different obstacles considered Different obstacles considered Objectives: Objectives: quantification of existing ventilation quantification of existing ventilation to study 14 scenarios of heavy hydrogen leak to study 14 scenarios of heavy hydrogen leak optimization and improvement of ventilation system optimization and improvement of ventilation system
fluidyn-VENTCLIM 1 st floor RdC Geometry presentation
fluidyn-VENTCLIM Lateral view Top view 3D View Blow duct Extraction duct 1 st floor RdC reservoirs Mesh used
fluidyn-VENTCLIM Recirculation zone blowing Velocity in 2 vertical planes
fluidyn-VENTCLIM blowing Velocity in 2 horizontal planes Recirculation zone
fluidyn-VENTCLIM blowing Velocity in 2 section planes
fluidyn-VENTCLIM source direction concentrations of H 2 on the planes 3D concentration contours of H 2 H 2 leak: Concentration fields
fluidyn-VENTCLIM source concentrations of H 2 on the planes 3D concentration contours of H 2 Aspiration duct H 2 concentration in the building
fluidyn-VENTCLIM A Case Study Carrefour Mall Parking A Case Study Carrefour Mall Parking Natural ventilation in a multi-storey parking: Effectiveness in fire situation Effectiveness in fire situation
fluidyn-VENTCLIM Context and study objectives Context : Extension of an existing building Flow modification in the parking Change in ventilation conditions Objectives: Evaluate new ventilation alternatives in case of vehicle fire in the parking
fluidyn-VENTCLIM Study flow Geometry and mesh creation Simulation of a case without fire Obtaining a steady result Obtaining a steady result Using this result as CI for the simulations with fire Using this result as CI for the simulations with fire Simulation of 2 scenarios with fire Identical power : 8 MW (1 big heavy vehicle or 2 small heavy vehicles) Identical power : 8 MW (1 big heavy vehicle or 2 small heavy vehicles) 2 different positions 2 different positions
fluidyn-VENTCLIM Parking and its surroundings Initial building Presence of the extension modifies flow in the parking Geometry creation and Mesh generation Geometry creation and Mesh generation
fluidyn-VENTCLIM Numerical model of the parking Ramp towards the adjoining parking Escalators Access ramps to floors & walls Staircase Block representing the cars Wall around the floors
fluidyn-VENTCLIM Velocity field in the domain Velocity field at z=8m Parking : weak velocity zone Building: obstacle
fluidyn-VENTCLIM Velocity field in the parking Sections along the X axis
fluidyn-VENTCLIM Velocity vectors in the parking Z=1m Z=5m Z=7m Z=11.3m
fluidyn-VENTCLIM Ground floor Absence of vehicles in the lane reserved for firemen Fire position in a weak velocity zone
fluidyn-VENTCLIM Smoke evolution Iso-surface of CO 2 mass concentration = 0.2 t=100 s t=300 s t=610 s
fluidyn-VENTCLIM Temperature fields t = 100 st = 300 s t = 600 s
fluidyn-VENTCLIM Temperature field : Stratification t = 300 s
fluidyn-VENTCLIM A Case Study Ventilation in industrial premises
fluidyn-VENTCLIM Context Efficiency of the air filters Complex ventilation system (suction, blowing and filter) Weak rate of emission 2 species (NH 3 & H 2 S)
fluidyn-VENTCLIM Geometry Suction Blower Filter
fluidyn-VENTCLIM Results: H 2 S concentration 3D view of H2S concentration Concentration at the top
fluidyn-VENTCLIM Results: NH 3 distribution 3D View Concentration distribution in a plane
fluidyn-VENTCLIM Ventilation in industrial premises and waste treatment
fluidyn-VENTCLIM Study context Industrial waste treatment Pollutant emissions harmful to man Threshold « Health » Pollutant emissions harmful to man Threshold « Health » Explosive gases Lower explosive limit Explosive gases Lower explosive limit Evaluation of proposed ventilation capabilities Optimisation of future extraction systems Pollutant ppmvMass Fraction LEL e-3 Health e-3
fluidyn-VENTCLIM Geometry and emission sources Pumping the shafts Shaft sections Storage bucket Closed doors Emptying shafts
fluidyn-VENTCLIM Ventilation setup Valves ceiling Extractors (ground)
fluidyn-VENTCLIM Domain Mesh ZOOM Non conformed mesh
fluidyn-VENTCLIM Results : isosurface 500 ppm Health threshold
fluidyn-VENTCLIM Pollutant mass fraction Horizontal plane at 80 cm from the ground
fluidyn-VENTCLIM Velocity Distribution
fluidyn-VENTCLIM Fresh air flow from valves
fluidyn-VENTCLIM 146, Ring Road, Sector 5, H.S.R LAYOUT BANGALORE INDIA : : , boulevard de la Libération SAINT-DENIS FRANCE : : Fluidyn Client Suppport Centres
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