Category
- Microscopy and Imaging » Flow Measurement
Booking Details
Shadowgraphy
Facility Management Team and Location
sudar@aero.iitb.ac.in
25767124
- Prof. Hrishikesh Gadgil
- Prof. Sreedhara Sheshadri
- Prof. Sridhar Balasubramanian
- Prof. Arindrajit Chowdhury
- Prof. M S Tirumkudulu
- Prof. Sudarshan Kumar
Facility Features, Working Principle and Specifications
Working Principle
Image based spray diagnostic system developed by LaVision. This technique is based on the following optical techniques:
Particle Image Velocimetry (PIV) measures whole velocity fields by taking two images shortly after each other and calculating the distance individual particles travelled within this time. From the known time difference and the measured displacement the velocity is calculated. Since the flow can be quite fast one has to avoid blurred images and that's one reason to use laser pulses. They are only 6-10 ns long and freeze any motion. The other reason is that only laser light can be focused into a thin enough light sheet so that only particles in that plane are imaged. Otherwise the scattered light from particles in other planes would make this measurement impossible. A special camera is utilized so that it can store the first image (frame) fast enough to be ready for the second exposure. The "dead" time between the frames when the camera is "blind" is very short down to 100 ns.
LaVision FlowMaster systems measure instantaneously two and three dimensional velocity vector fields from scattered light patterns of particles or droplets seeded into the flo w(liquid or gas). Techniques like Particle Image Velocimetry (PIV) and Particle Tracking Velocimetry (PTV) are supported.
The shadowgraphy technique (backlighting) is used to visualize particles (e.g. droplets from a spray or bubbles in liquid). Shadowgraph employs an expanded collimated beam of light from a laser that traverses the field of disturbance. If the disturbance is one of varying refractive index, the individual light rays passing through the test section are refracted and bent out of their original path. This causes a spatial modulation of the light-intensity distribution with respect to the original intensity on the screen. The resulting pattern is a shadow of the refractive index field prevailing in the region of the disturbance. A He-Ne laser is expanded and collimated to a suitable diameter by a beam expander. The collimated beam passes through the test section being investigated. The beam emerging from the exit window falls on a screen resulting in the shadowgraph image. The images may be recorded as individual frames or a video sequence by a suitable camera..
Features
- High speed LIF systems
- unable Nd:YAG laser module for OH-LIF imaging
- High speed spectral analysis of transient processes
- Complete hardware control using DaVis software
- Flexible beam delivery and sheet forming optics
- Most efficient LIF excitation technique for each application and flame radical
- Combination of techniques, multi-parameter laser imaging
- Accurate hardware and size calibration
- Comprehensive on-line image evaluation and data processing
- Hardware compatible with LaVision's PIV systems
- High efficient diffuser for speckle-free illumination
- Flexible definition of image acquisition sequences including delays, trigger bursts and synchronizing to external events
- 2D and 3D visualization of image data, combination of vector data and images, extraction of profiles, user defined color lookup tables, variable color resolution and zoom function
- Smoothing and many other filter operations for image and vector data (Gauss, Laplace, Sobel, Erosion, customizable filters ...)
- Data import / export to TecPlot, ASCII, BMP, JPG, TIFF, VI, PS, FTS, ...
Technical Specifications
- DaVis 8.1 Software Packages & Integrated Command Language :
- LaVision flow master
- LaVision particle master
- Quantel EverGreen Integrated Cooling and Electronics (Laser Power Supply) :
- Operational temperature range: 18oC - 28oC
- Storage temperature range: 5oC - 50oC
- Laser Head mass15.5 lb [7.0 kg]
- ICE weight: Empty: 35 lb [15.9 kg]
- Full: 40 lb [18.1 kg]
- Laser wavelength: 532 nm
- Output energy: EVG00145 ≤145 mJ per pulse
- Beam near field profile: Flat-top, Uniform
- Polarization: linearly polarized
- Maximum repetition rate: up to 15 Hz
- Laser pulse width: (FWHM) less than or equal to 10 nanoseconds at nominal energy
- Coolant: distilled water
- Power requirements: 100-240 VAC, 50-60 Hz
- Laser Head sealing: sealed to IP 67 specification
- Power supply sealing sealed to IP 21 specification
- Laser vibration compliance: MIL-STD-810F Procedure 1 Category 10
- Laser Source :
- Nd:YAG laser by the LaVision Programmable Timing Unit (PTU)
- Laser material is a crystal where Nd3+ ions are incorporated in a YAG (Yttrium, Aluminum, Garnet) crystal.
- Pump usually is a krypton flashlamp or a smaller semiconductor laser.
- Dual oscillator i.e double pulse
- Charged Couple Device Camera Unit (ImagerProSX 5M) with IRO (Intensified Relay Optics) :
- Double shutter two images with 600 ns min. interframing time
- Resolution (hXv): 2448 pixel X 2050 pixel
- Sensor type: Sony ICX625
- Optical size: 2/3"
- Pixel size: 3.45 µm X 3.45 µm
- Spectral range: 400 - 850 nm
- Max. frame rate: (at full resolution) 14.2 fps
- Partial scan: yes
- Data output type: Gigabit Ethernet (1000 Mbits/s)
- Power requirements: +12 to +24 VDC, ≤1% ripple ≤5 W @ 12 V
- Operating temperature: 5 - 40 °C
- Size (l x w x h): 100 mmX57 mmX45 mm (without lens adapter or connectors)
- Weight: 380 g
- High Efficiency Diffuser :
- Allows incoming beam diameters of max. 8mm
- Calibration target 5 mm/ 200 lines
- Min. recommended laser power: 15 mJ, 527-532 nm
- Light output diameter: 120 mm
- Light output wavelength: 574-580 nm
- Light output pulse duration (@ 5 ns laser): 20 ns
- Long Distance Microscope (LDM) :
- Model: QM100
- Type: Maksutov Cassegrain Catadioptric
- Working Range: 150 mm (6 ") to 35 mm (14 "), subject plane to front element
- Clear Aperture: 63 mm (2.5 ")
- Back focal length: 70 mm (2.75 ") minimum measured from back plate
- Sheet Optics :
- Sheet thickness: 0.5 mm - 2.5 mm (adjustable, but dependant on M2 and size of Laser beam).
- Divergence lenses: f = -20 mm and -10 mm. 1108406 and 1108516 additionally with f=-50mm.
- Working distance: 300 mm - 2000 mm.
- Dimensions: approx. Ø43 mm X 90 mm.
Instructions for Registration, Sample Preparation, User Instructions, Precautionary Measures and Charges
Internal Users
- Only online registration through the IRCC webpage will be accepted, no paper forms.
- The online registration is available here
External Users
- To avail the IBSD Facility at combustion research laboratory, Registration is absolutely essential.
- For Registration, users can send the requisition letter from Head/Guide of the Organization / Department letterhead with advance payment in the form of demand draft .The Demand Draft should be in the favour of “The Registrar, IIT Bombay".
- Only one registration will be accepted at a time.
- Appointment will be given as per queue and user would be informed by e-mail
- The users will be informed about their date and time of slot by email. If user cannot come, a mail should be immediately sent to ibsd@iitb.ac.in to cancel his/her slot.
- Any query related to IBSD facility can be emailed on the address : ibsdf@iitb.ac.in
User Type
Charges
Industry & Other Non Gov. Agencies: INR 25,000/- per day
Academic Institutes: INR 10,000/- per day
National R&D Labs.: INR 15,000/- per day
- User has to bring distilled water.
- Experiments should be discussed with PI/TA and the facility in-charge before proceeding.
- Bring a new blank CD for copying the images. USB drives are strictly not allowed due to virus threat.
- Avoid eye and skin exposure to direct or scattered radiation. Use protective eyewear all the time when operating the laser.
- Wear clothes and gloves which cover arms and hands to avoid skin damage when handling in the optical path. Especially UV-radiation can cause skin cancer.
- While working with lasers do not wear reflective jewelry like watches and rings, as these might cause accidental hazardous reflections.
- Operate the laser at the lowest beam intensity possible.
- LaVision systems include devices which are equipped with delicate lenses and CCDs (scientific camera system). To reduce repair costs and downtimes and to increase the reliability and lifetime of your system it is extremely important to keep the optics clean and free from dust.
- Do not scratch or rub on lenses.
Applications
- Investigation of combustion phenomenon in:
- Flames
- Burners
- Jet engines
- Furnaces
- Propulsion systems
- Chemical reactors
- Shock tubes
- Flame front visualization & propagation
- Flame radicals' distribution (OH, NO, CH, etc.)
- Visualization of pollutant and soot formation
- Flame structure and stability
- Soot concentration and size of primary soot particles
- Structural analysis of turbulent flames
- Visualization of exhaust gas recirculation (EGR)
- Quantitative spray pattern analysis of flat, axial, and radial spray images
- Investigation of droplet or particle size distributions in various applications such as spray atomization, bubbles, and particle flows, including:
- Visualizing particles and droplets
- Gathering the following properties:
- Droplets size
- Droplets position
- Droplets shape & velocity
- Droplets number density
- Droplets mass flux