Current research projects

Image Test rigs for refrigeration and heat pump technology
Image Brine (water)-water heat pump
Image In-Situ-Swelling Behaviour of Polymer Materials in Flammable Fluids
Image Characterisation of Superconductors in Hydrogen Atmosphere
Image Hybrid- Fluid for CO2-Sublimation Cycle
Image Optimizing HVAC operation with machine learning
Image Innovative cryogenic cooling system for the recondensation / liquefaction of technical gases up to 77 K
Image Cool Up
Image Non- invasive flow measurements
Image IO-Scan - Integral measuring optical scanning method
Image Combined building and system simulation
Image Investigation of material-dependent parameters
Image Low Temperature Measuring Service
Image Heat2Power
Image Humidifier System for High-Purity Gases
Image Tensile and compression testing

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Non- invasive flow measurements

Industry

Dipl.-Ing. Dirk Keßlau

+49-351-4081-724

Measurment Dates Available

PDPA - flow fields and particle sizes

3D Phasen- Doppler Particle Anemometer (PDPA)

The Institut für Luft- und Kältetechnik (ILK) uses an ultramodern 3D Phase Doppler Particle Analyzer for non- invasive measurement of velocities of flows and particle sizes in flowing media.  A high performance water cooled Argon- Ion Laser offers the possibility for measuring particle sizes (0.5 - 800 µm) and flow rates (from 0 m/s to supersonic) even in zones of mist or vapour.

Measurands

This measurement technique allows the detection of temporally and spatially velocity fields (3D) in high resolution without influencing the flow even in combustion engines and sprays. Of particular interest is the measurement of aerosols of fluids with a high vapour pressure (including water) because their particle size distribution change in sampling systems and analyzers due to evaporation processes.

Measuring principle

The example below describes the measuring principle for one spatial direction.

In a limited measuring volume two laser beams intersect (figure 1, left) forming an interference pattern (figure 1, center). A particle crossing the measuring volume scatters light with the Doppler frequency fD which is proportional to the velocity of the particle. Velocity u can be calculated as the product of Doppler frequency and the distance of the fringes of the interference pattern (δf): u = δf⋅fD If the frequency of the two intersecting laser beams is equal, a stationary interference pattern is formed. If two particles equal in the amount of speed but with opposing directions of flight cross the measuring volume scatterd light equal in Doppler frequency is detected. It is not possible to determine the direction of flight. Technically this problem is solved by a frequency shift between the laser beams. This results in a moving interference pattern. Thereby light scattered by a particle has a frequency f of Δf ± fD depending of the direction of flight. Besides determination of the flow direction measurement of small flow rates becomes possible. The droplet size determination is based on one of the Doppler signals (figure 1, right) detected on three spatially separated detectors. The separation of the detectors causes a phase shift of the signal which correlates with the curvature radius of the droplets. The knowledge of the curvature radius allows the determination of the radius of the droplets. Furter information an brochures can be found at TSI Inc..

Services: measurement and testing

The PDPA allows for example the determination of flow rates and particles sizes of sprays, the evaluation of droplet separators and the measurement of velocity fields behind duct installations. The following figure as an example shows the flow profile of a flat suction hood.

By the help of this data you are able to benchmark or improve the performance of your products and evaluate the results of your flow simulations. If you have got other flow problems we would also like supporting you solving them.

Consulting and Research Services

You wish to develop your products? Due to our long- standing experience in flow and aerosol measuring techniques and our equipment with the recent measuring instruments we are able to support you. 


Your Request

Further Projects - Research and Development

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Hydrogen and methane testing field at the ILK

Simultaneously pressures up to 1,000 bar, temperatures down to –253°C

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Low noise and non metallic liquid-helium cryostat

Low-noise Magnetic Field Cryostat for SQUID-Applications

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Cryostats, Non-Metallic and Metallic

position indenpendent, highest endurance, tiltable for liquid helium and liquid nitrogen

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Calibration of Low Temperature Sensors

According to the comparative measurement method