Current research projects

Image High Capacity Pulse Tube Cooler
Image Combined building and system simulation
Image Energy efficiency consulting - cogeneration systems
Image Corrosion inhibitor for ammonia absorption systems
Image Investigation of material-dependent parameters
Image Reduction of primary noise sources of fans
Image Electrical components in refrigeration circuits
Image Humidifier System for High-Purity Gases
Image Characterisation of Superconductors in Hydrogen Atmosphere
Image Ice Slurry Generation
Image Filter Tests
Image Investigation of materials
Image Computational fluid dynamics CFD
Image Investigation according to DIN EN ISO 14903
Image Software modules
Image Test rigs for refrigeration and heat pump technology

You are here:  Home /  Research and Development


Swirl-free on the move...

2019-2021

Christian Friebe

+49-351-4081-5313

project started

CFturbo

...with a contra-rotating fan

In many areas centrifugal fans are used for conveying air. Depending on the installation situation and requirements, the use of a housingless fan, a so-called free-running impeller, can be feasabile. A typical application is, for example, the air conditioning unit (see Figure 1). A disadvantage is the functionally swirling discharge from the impeller. This may lead to poorer acoustics, more pressure loss and lower performance in downstream components such as filters, silencers or heat exchangers.

According to the state of the art, the swirl can be removed from the flow by various means. On the one hand, the use of a spiral housing is possible, on the other hand, the use of discharge guidevanes are possible. The volute casing contradicts the purpose of the free-running impeller and still has a high air speed at the outlet. Both the volute casing and the guide vanes can both help to convert the existing dynamic pressure from the impeller into usable static pressure, but neither is capable of transferring additional energy to the fluid.
Therefore, the task of this research project is to create a swirl-free outflow from an impeller using a new type of contra-rotating impeller. The mode of operation shown in Figure 2 is based on the speed triangles of the two counter-rotating impellers.
On the basis of a speed and volume flow dependent coordination of the two impellers with each other, a shock-free flow is achieved with the contra-rotating design of the second impeller and the relative speed w is further decelerated. Due to the existing pre-swirl, a swirl-free pressure reduction can be achieved despite the reduction in speed.

The following subtasks must be clarified in order to successfully deal with the topic:

  • Design, tuning and optimization of the impellers
  • Development of a suitable drive concept
  • Reduction of leakage in the gap between the two impellers
  • Optimization of the acoustic properties
  • Development of a swirl detector for the control of the fan

The use of a contra-rotating centrifugal fan provides the following advantages:

  • A swirl-free outflow for higher static efficiency, comparable to a housing or a guide vane
  • Optimum flow to the downstream components from a thermodynamic and flow mechanics point of view
  • Optimum efficiency by adjusting the speeds
  • Greater performance with the same construction volume

Your Request

Further Projects - Research and Development

Image

Hydrogen and methane testing field at the ILK

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

Image

Low noise and non metallic liquid-helium cryostat

Low-noise Magnetic Field Cryostat for SQUID-Applications

Image

Cryostats, Non-Metallic and Metallic

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

Image

Calibration of Low Temperature Sensors

According to the comparative measurement method