Klimafibel

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	1.	Climate as a Public Interest in Planning and Zoning
	2.	Characteristics and Forms of the Urban Climate
	3.	Energy-Conscious Planning and Zoning
	4.	Methods of Information Acquisition for Planning (Measurements, Wind Tunnels, Numerical Modelling)
	4.1	Measurements
	4.1.1	Stationary Measurements
	4.1.2	Measurements with mobile measurement devices
	4.1.3	Tracer Experiments
	4.1.4	Vertical Soundings
	4.2	Wind Tunnel
	4.2.1	Overview
	4.2.2	Operation and Investigation Methods
	4.2.2.1	Visualization of flows and pollutant dispersion by smoke
	4.2.2.2	Wind Velocity Measurements
	4.2.2.3	Measurement of Concentration Distribution in Dispersal Experiments
	4.2.3	Locations of Wind Tunnels
	4.3	Numerical Modelling of Flow and Transport Processes
	4.3.1	The Wind Field Model DIWIMO
	4.3.2	The Cold-Air Flow Model KALM and KLAM 21
	4.3.3	The Model STREET for Estimating Traffic-Produced Pollution
	4.3.4	The Model MLuS-02 for Calculating Pollutant Dispersal on Roads Without Dense Peripheral Development
	4.3.5	The Model PROKAS for Calculating Air Pollution on Roads
	4.3.6	The Micro-Scale Model MISKAM
	4.3.7	Mesoscale Terrain Climatic Models
	4.3.8	The Urban Climate Models RayMan , ENVI-met and MUKLIMO_3
	5.	Climatic and Air Hygiene Maps as Aids for Planning and Zoning (Example: Climate Atlas Federation Region Stuttgart)
	6.	Recommendations for Planning
	7.	Bibliography
	8.	Thematic Websites
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METHODS OF INFORMATION ACQUISITION FOR PLANNING (MEASUREMENTS, WIND TUNNELS, NUMERICAL MODELLING)

4.2.2.1 Visualization of flows and pollutant dispersion by smoke

Smoke is blown into the boundary layer through special inlets to visualise the flow. Special changes in the flow, e.g. wake eddies, can so be distinguished (Figure. 4/10a and Figure 4/10b).

Smoke can also be blown through potential pollutant sources (like a chimney) in order to visualise the dispersion of the pollutants. The dispersion of the smoke within the area under investigation as well as its dilution are visualised and can be photographed or videotaped. Quantitative conclusions on the concentrations are not possible however. But the method can be very useful for a general illustration of this kind of problem.

Fig. 4/10a: Follow-up zone of a building in a wind tunnel , with smoke visible , Source: Engineering Office Theurer

Fig. 4/10b: Vertical flow field of a building in a wind tunnel, with smoke visible, Source: University of Karlsruhe , Institute for Hydromechanics
Flow field as animation